Offshore universal riser system

ABSTRACT

An offshore universal riser system may include a valve module which selectively permits and prevents fluid flow through a flow passage extending longitudinally through a riser string. An anchoring device may releasably secure the valve module in the passage. A method of constructing a riser system may include the steps of installing the valve module in the passage, and installing at least one annular seal module in the passage. The annular seal module may prevent fluid flow through an annular space between the riser string and a tubular string positioned in the passage. Drilling methods may include injecting relatively low density fluid compositions into the annular space, and selectively varying a restriction to flow through a subsea choke in a drilling fluid return line. The riser string, including housings for the various modules and external control systems, may be dimensioned for installation through a rotary table.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a division of prior application Ser. No. 12/299,411filed on Jun. 1, 2009, which claims priority to a national stageapplication under 35 USC §371 of International Application No.PCT/US07/83974 filed on Nov. 7, 2007, which claims the benefit of thefiling date of U.S. Provisional Application No. 60/864,712 filed on Nov.7, 2006. The entire disclosures of these prior applications areincorporated herein by this reference.

BACKGROUND

The present invention relates generally to marine riser systems and, inan embodiment described herein, more particularly provides an offshoreuniversal riser system.

Risers are used in offshore drilling applications to provide a means ofreturning the drilling fluid and any additional solids and/or fluidsfrom a borehole back to surface. Riser sections are sturdily built asthey have to withstand significant loads imposed by weights they have tocarry and environmental loads they have to withstand when in operation.As such, they have an inherent internal pressure capacity.

However, this capacity is not currently exploited to the maximum extentpossible. Many riser systems have been proposed to vary the density offluid in the riser but none have provided a universally applicable andeasily deliverable system for varying types of drilling modes. Theytypically require some specific modification of the main components of afloating drilling installation, with the result that they are customsolutions with a narrow range of application due to costs and designlimitations. For example, different drilling systems are required fordifferent drilling modes such as managed pressure drilling, dual densityor dual gradient drilling, partial riser level drilling, andunderbalanced drilling.

An example of the most common current practice is illustrated by FIG. 1,which is proposed in U.S. Pat. No. 4,626,135. To compensate for movementof a floating drilling installation, a slip joint SJ (telescopic joint)is used at an upper end of a riser system. This slip joint consists ofan inner barrel IB and an outer barrel OB that move relative to eachother, thus allowing the floating structure S to move without breakingthe riser R between the fixed point wellhead W and the moving pointdiverter D (which is where drilling fluid is returned from the top ofthe riser R).

Also depicted in FIG. 1 are a rig structure S, rig floor F, rotary tableRT, choke manifold CM, separator MB, shale shaker SS, mud pit MP, chokeline CL, kill line KL, booster line BL and rigid flowline RF. Theseelements are conventional, well known to those skilled in the art andare not described further.

A ball joint BJ (also known as a flex-joint) provides for some angulardisplacement of the riser R from vertical. The conventional methodinterprets any pressure in the riser R due to flow of pressurized fluidsfrom wellhead W as an uncontrolled event (kick) that is controlled byclosing the BOP (blowout preventer) either by rams around the tubularstherein, or by blind rams if no tubulars are present, or by shear ramscapable of cutting the tubulars.

It is possible for the kick to enter the riser R, and then it iscontrolled by closing the diverter D (with or without tubulars present)and diverting the undesired flow through diverter lines DL. In the '135patent the concept of an annular blow out preventer used as a gashandler to divert the flow of gas from a well control incident isdescribed. This allows diversion of gas in the riser R by closing aroundthe tubulars therein, but not when drilling, i.e., rotating the tubular.

In FIG. 1, seals between the outer barrel OB and inner barrel IB aresubjected to much movement due to wave motion, and this causes alimitation in the pressure sealing capacity available for the riser R.In fact, the American Petroleum Institute (API) has established pressureratings for such seals in its specification 16F, which calls for testingto 200 psi (pounds per square inch). In practice, the common upper limitfor most designs is 500 psi.

There are some modifications that can be made to the slip joint SJ, anexample of which is described in U.S. Patent Application No.US2003/0111799A1, to produce a working rating to 750 psi. In practice,the limitation on the slip joint SJ seals has also led to an acceptedstandard in the industry of the diverter D, ball joint BJ (alsosometimes replaced by a unit known as a flex-joint) and other parts ofthe system (such as valves on the diverter line DL) having a typicalindustry-wide rating of 500 psi working pressure.

The outer barrel OB of the slip joint SJ (telescopic joint) also acts asan attachment point for a tension system that serves to keep the riser Rin tension to prevent it from buckling. This means that a leak in theslip joint SJ seals involves significant downtime in having to lift theentire riser R from the subsea BOP (blowout preventer) stack in order toservice the slip joint SJ. In practice this has meant that no floatingdrilling installation service provider or operating company has beenwilling to take the risk to continuously operate with any pressure inthe riser R for the conventional system (also depicted in FIG. 3 a).

U.S. Patent Application No. 2005/0061546 and U.S. Pat. No. 6,913,092have addressed this problem by proposing the locking closed of the slipjoint SJ, which means locking the inner barrel IB to the outer barrelOB, thus eliminating movement across the slip joint seal. The riser R isthen effectively disconnected from the ball joint BJ and diverter D asshown in FIG. 2.

The riser R is closed by the addition of a rotating blowout preventer 70on top of the locked closed slip joint SJ. This effectively decouplesthe riser R from any fixed point below the rotary table RT.

Also depicted in FIG. 2 are vertical beams B, adapter or crossover 22,rotatable tubular 24 (such as drill pipe) and T-connectors 26. Theseelements are conventional and are not described further here.

This method has been used and allowed operations with a limit of 500 psiinternal riser pressure, with the weak point still being the slip jointseals. However, decoupling the riser R from the fixed rig floor F meansthat it is only held by the tensioner system T1 and T2.

This means that the top of the riser R is no longer self centralizing.This causes the top of an RCD 80 (rotating control device) of theblowout preventer 10 to be off center as a result of ocean currents,wind or other movement of the floating structure. This introducessignificant wear on the sealing element(s) of the RCD 80, which isdetrimental to the pressure integrity of the riser system.

Also, the riser system of FIG. 2 introduces a significant safety hazard,since substantial amounts of easily damaged hydraulic hoses used in theoperation of the RCD 80, as well as pressurized hose(s) 62 and safetyconduit 64, are introduced in the vicinity of riser tensioner wiresdepicted as extending upwardly from the slip joint SJ to sheaves at thebottom of the tensioners T1, T2. These wires are under substantial loads(on the order of 50 to 100 tons each) and can easily cut through softerrubber goods (such as hoses). The '092 patent suggests the use of steelpipes, but this is extremely difficult to achieve in practice.

Furthermore, the installation and operation requires personnel toperform tasks around the RCD 80, a hazardous area with the relativemovement between the floating structure S to the top of the riser R. Allof the equipment does not fit through the rotary table RT and diverterhousing D, thus making installation complex and hazardous. As a result,use of the system of FIG. 2 has been limited to operations in benign seaareas with little current, wave motion, and wind loads.

A summary of the evolution for the art for drilling with pressure in theriser is shown in FIGS. 3 a to 3 c. FIG. 3 a shows the conventionalfloating drilling installation set-up. This consists typically of an 18¾inch subsea BOP stack, with a LMRP (Lower Marine Riser Package) added toallow disconnection and prevent loss of fluids from the riser, a 21 inchmarine riser, and a top configuration identical in principle to the '135patent discussed above. This is the configuration used by a largemajority of today's floating drilling installations.

In order to reduce costs, the industry moved towards the idea of using aSBOP (surface blowout preventer) with a floating drilling installation(for example, U.S. Pat. No. 6,273,193 as illustrated in FIG. 4), wherethe 21 inch riser is replaced with a smaller high pressure riser cappedwith a SBOP package similar to a non-floating drilling installationset-up as illustrated in FIG. 3 b. This design evolved to dispensingcompletely with the subsea BOP, thus removing the need for choke, kill,and other lines from the sea floor back to the floating drillinginstallation and many wells were drilled like this in benign oceanareas.

FIG. 4 depicts a riser 74, slip joint 78, collar 102, couplings 92,hydraulic tensioners 68, inner riser 66, load bearing ring 98, load shim86, drill pipe 72, surface BOP 94, line 76, collar 106 and rotatingcontrol head 96. Since these elements are known in the art, they are notdescribed further here.

In attempting to take the concept of a SBOP and high pressure riserfurther into more environmentally harsh areas, a subsea component fordisconnection (known as an environmental safeguard ESG system) andsecuring the well in case of emergency was re-introduced, but not as afull subsea BOP. This is shown in FIG. 3 c with another evolution ofrunning the SBOP below the water line and tensioners above to providefor heave on floating drilling installations with limited clearance. Themethod of U.S. Pat. No. 6,913,092 is shown in FIG. 3 d for comparison.

In trying to plan for substantially higher pressures as experienced inunderbalanced drilling where the formation being drilled is allowed toflow with the drilling fluid to surface, the industry has favoreddesigns utilizing an inner riser run within the typical 21 inch marineriser as described in U.S. Patent Application 2006/0021755 A1. Thisrequires a SBOP as shown in FIG. 3 e.

Drawbacks of the systems and methods described above include that theyrequire substantial modification of the floating drilling installationto enable the use of SBOP (surface blowout preventers) and the majorityare limited to benign sea and weather conditions. Thus, they are notwidely implemented since, for example, they require the floatingdrilling installation to undergo modifications in a shipyard.

Methods and systems as shown in U.S. Pat. Nos. 6,230,824 and 6,138,774attempt to dispense totally with the marine riser. Methods and systemsdescribed in U.S. Pat. Nos. 6,450,262, 6,470,975, and U.S. PatentApplication 2006/0102387A1 envision setting an RCD device on top of thesubsea BOP to divert pressure from the marine riser, as does U.S. Pat.No. 7,080,685 B2. All of these patents are not widely applied as theyinvolve substantial modifications and additions to existing equipment tobe successfully applied.

FIG. 5 depicts the system described in U.S. Pat. No. 6,470,975.Illustrated in FIG. 5 are pipe P, bearing assembly 28, riser R, chokeline CL, kill line KL, BOP stack BOPS, annular BOP's BP, ram BOP's RBP,wellhead W and borehole B. Since these elements are known in the art,further description is not provided here.

A problem with the foregoing systems that utilize a high pressure riseror a riserless setup is that one of the primary means of deliveringadditional fluids to the seafloor, namely the booster line BL that is atypical part of the conventional system as depicted in FIG. 3 a, isremoved. The booster line BL is also indicated in FIGS. 1 and 2. So, thesystems shown in FIGS. 3 b and 3 c, while providing some advantages,take away one of the primary means of delivering fluid into the riser.Even when the typical booster line BL is provided, it is tied in to thebase of the riser, which means that the delivery point is fixed.

There is also an evolution in the industry to move from conventionaldrilling to closed system drilling. These types of closed systems aredescribed in U.S. Pat. Nos. 6,904,981 and 7,044,237, and require theclosure and (by consequence) the trapping of pressure inside the marineriser in floating drilling installations. Also, the introduction of amethod and system to allow continuous circulation as described in U.S.Pat. No. 6,739,397 allows a drilling circulation system to be operatedat constant pressure as the pumps do not have to be switched off whenmaking or breaking a tubular connection. This allows the possibility ofdrilling with a constant pressure downhole, which can be controlled by apressurized closed drilling system. The industry calls this ManagedPressure Drilling.

With the conventional method of FIG. 3 a, no continuous pressure can bekept in the riser. In FIG. 6 a, fluid flow in the riser system of FIG. 3a is schematically depicted. Note that the riser system is open to theatmosphere at its upper end. Thus, the riser cannot be pressurized,other than due to hydrostatic pressure of the fluid therein. Since thefluid (mud, during drilling) in the riser typically has a density equalto or only somewhat greater than that of the fluid external to the riser(seawater), this means that the riser does not need to withstandsignificant internal pressure.

With the method of U.S. Pat. No. 6,913,092 (as depicted in FIG. 3 d),the pressure envelope has been taken to 500 psi, however, with thesubstantial addition of hazards and many drawbacks. It is possible toincrease the envelope by the methods shown in FIGS. 3 b, 3 c and 3 e.However, the addition of a SBOP (surface BOP) to a floating drillinginstallation is not a normal design consideration and involvessubstantial modification, usually involving a shipyard with theconsequence of operational downtime as well as substantial costsinvolved, as already mentioned above.

The systems mentioned earlier in U.S. Pat. Nos. 6,904,981 and 7,044,237discuss closing the choke on a pressurized drilling system, and usingmanipulation of the choke to control the backpressure of the system, inorder to control the pressure at the bottom of the well. This methodworks in principle, but in field applications of these systems, whendrilling in a closed system, the manipulation of the choke can causepressure spikes that are detrimental to the purpose of these inventions,i.e., precise control of the bottom hole pressure.

Also, a peculiarity of a floating drilling installation is, that when aconnection is made, the top of the pipe is held stationary in the rotarytable (RT in FIGS. 1 and 2). This means that the whole string of pipe inthe wellbore now moves up and down as the wave action (known as heave inthe industry) causes the pressure effects of surge (pressure increase asthe pipe moves into the hole) and swab (pressure drop as the pipe movesout of the hole). This effect already causes substantial pressurevariations in the conventional method of FIG. 3 a.

When the system is closed by the addition of an RCD as shown in FIG. 3d, this effect is even more pronounced by the effect of volume changesby the pipe moving in and out of a fixed volume. As the movement of apressure wave in a compressed liquid is the speed of sound in thatliquid, it implies that the choke system would have to be able torespond at the same or even faster speed. While the electronic sensorand control systems are able to achieve this, the mechanicalmanipulation of the choke system is very far from these speeds.

Development of RCD's (rotating control devices) originated from landoperations where typically the installation was on top of the BOP(blowout preventer). This meant that usually there was no furtherequipment installed above the RCD. As access was easy, almost all of thecurrent designs have hydraulic connections for lubricating and coolingbearings in the RCD, or for other utilities. These require the externalattachment of hoses for operation.

Although some versions have progressed from surface type to beingadapted for use on the bottom of the sea (such as described in U.S. Pat.No. 6,470,975), they fail to disclose a complete system for achievingthis. Some systems (such as described in U.S. Pat. No. 7,080,685)dispense with hydraulic cooling and lubrication, but require a hydraulicconnection to release the assembly.

Furthermore, the range of RCD's and alternatives available means that acustom made unit to house a particular RCD design is typically required(such as described in U.S. Pat. No. 7,080,685). The '685 patent providesonly for a partial removal of the RCD assembly, leaving the body onlocation.

Many ideas have been tried and patents have been filed, but the fieldapplication of technology to solve some of the shortcomings in theconventional set-up of FIG. 3 a has been limited. All of these modifythe existing system in a custom manner, thereby taking away some of theflexibility. There exist needs in the present industry to provide asolution to allow running a pressurized riser for the majority offloating drilling installations to allow closed system drillingtechniques, especially managed pressure drilling, to be safely andexpediently applied without any major modification to the floatingdrilling installation.

These needs include, but are not limited to: the capability topressurize the marine riser to the maximum pressure capacity of itsmembers; the capability to be safely installed using normal operationalpractices and operated as part of a marine riser without any floatingdrilling installation modifications as required for surface BOPoperations or some subsea ideas; providing full-bore capability like anormal marine riser section when required; providing the ability to usethe standard operating procedures when not in pressurized mode;maintaining the weather (wind, current and wave) operating window of thefloating drilling installation; providing a means for damping thepressure spikes caused by heave resulting in surge and swabfluctuations; providing a means for eliminating the pressure spikescaused by movement of the rotatable tubulars into and out of a closedsystem; and providing a means for easily modifying the density of fluidin the riser at any desired point.

SUMMARY

In carrying out the principles of the present invention, a riser systemand associated methods are provided which solve one or more problems inthe art. One example is described below in which the riser systemincludes modular internal components which can be conveniently installedand retrieved. Another example is described below in which the risersystem utilizes rotating and/or non-rotating seals about a drill stringwithin a riser, to thereby facilitate pressurization of the riser duringdrilling.

The systems and methods described herein enable all the systems shown inFIGS. 3 a to 3 e to be pressurized and to have the ability to injectfluids at any point into the riser. Any modification to a riser systemwhich lessens the normal operating envelope (i.e. weather, current, waveand storm survival capability) of the floating drilling installationleads to a limitation in use of that system. The riser systems shown inFIGS. 3 b, 3 d and 3 e all lessen this operating envelope, which is amajor reason why these systems have not been applied in harsherenvironmental conditions. The system depicted in FIG. 3 c does notlessen this operating window significantly, but it does not allow forconvenient installation and operation of a RCD. All of these limitationsare eliminated by the systems and methods described below.

In order to reduce, or even optimally remove pressure spikes (negativeor positive from a desired baseline) from within a pressurized riser, adamping system is provided. A beneficial damping system in anincompressible fluid system includes the introduction of a compressiblefluid in direct contact with the incompressible fluid. This could be agas, e.g., Nitrogen.

An improved annular seal device for use in a riser includes a latchingmechanism, and also allows hydraulic connections between the annularseal device and pressure sources to be made within the riser, so that nohoses are internal to the riser. The latching mechanism may besubstantially internal or external to the riser.

The present specification provides a more flexible riser system, in partby utilizing a capability to interface an internal annular seal devicewith any riser type and connection, and providing adapters that arepre-installed to take the annular seal device being used. These can alsohave wear sleeves to protect sealing surfaces when the annular sealdevice is not installed. If an annular seal design is custom made forinstallation into a particular riser type, it may be possible to insertit without an additional adapter. The principle being that it ispossible to remove the entire annular seal device to provide the fullbore requirement typical of that riser system and install a safety/wearsleeve to positively isolate any ports that are open and provideprotection for the sealing surfaces when the annular seal device is notinstalled.

In one aspect, a riser system is provided which includes a valve modulewhich selectively permits and prevents fluid flow through a flow passageextending longitudinally through a riser string, and wherein a firstanchoring device releasably secures the valve module in the flowpassage.

In another aspect, a method of pressure testing a riser string isprovided which includes the steps of: installing a valve module into aninternal longitudinal flow passage extending through the riser string;closing the valve module to thereby prevent fluid flow through the flowpassage; and applying a pressure differential across the closed valvemodule, thereby pressure testing at least a portion of the riser string.

In yet another aspect, a method of constructing a riser system includesthe steps of: installing a valve module in a flow passage extendinglongitudinally through a riser string, the valve module being operativeto selectively permit and prevent fluid flow through the flow passage;and installing at least one annular seal module in the flow passage, theannular seal module being operative to prevent fluid flow through anannular space between the riser string and a tubular string positionedin the flow passage.

A drilling method is also provided which includes the steps of:connecting an injection conduit externally to a riser string, so thatthe injection conduit is communicable with an internal flow passageextending longitudinally through the riser string; installing an annularseal module in the flow passage, the annular seal module beingpositioned in the flow passage between opposite end connections of theriser string; conveying a tubular string into the flow passage; sealingan annular space between the tubular string and the riser stringutilizing the annular seal module; rotating the tubular string tothereby rotate a drill bit at a distal end of the tubular string, theannular seal module sealing the annular space during the rotating step;flowing drilling fluid from the annular space to a surface location; andinjecting a fluid composition having a density less than that of thedrilling fluid into the annular space via the injection conduit.

Another drilling method is provided which includes the steps of:connecting a drilling fluid return line externally to a riser string, sothat the drilling fluid return line is communicable with an internalflow passage extending longitudinally through the riser string;installing an annular seal module in the flow passage, the annular sealmodule being positioned in the flow passage between opposite endconnections of the riser string; conveying a tubular string into theflow passage; sealing an annular space between the tubular string andthe riser string utilizing the annular seal module; rotating the tubularstring to thereby rotate a drill bit at a distal end of the tubularstring, the annular seal module sealing the annular space during therotating step; flowing drilling fluid from the annular space to asurface location via the drilling fluid return line, the flowing stepincluding varying a flow restriction through a subsea choke externallyconnected to the riser string to thereby maintain a desired downholepressure.

Yet another drilling method includes the steps of: installing a firstannular seal module in an internal flow passage extending longitudinallythrough a riser string, the first annular seal module being secured inthe flow passage between opposite end connections of the riser string;sealing an annular space between the riser string and a tubular stringin the flow passage utilizing the first annular seal module, the sealingstep being performed while the tubular string rotates within the flowpassage; and then conveying a second annular seal module into the flowpassage on the tubular string.

A further aspect is a method which includes the steps of: installingmultiple modules in an internal flow passage extending longitudinallythrough a riser string, the modules being installed in the flow passagebetween opposite end connections of the riser string; inserting atubular string through an interior of each of the modules; and thensimultaneously retrieving the multiple modules from the flow passage onthe tubular string.

Another drilling method includes the steps of: sealing an annular spacebetween a tubular string and a riser string; flowing drilling fluid fromthe annular space to a surface location via a drilling fluid returnline; and injecting a fluid composition having a density less than thatof the drilling fluid into the drilling fluid return line via aninjection conduit.

Yet another drilling method includes the steps of: installing an annularseal module in an internal flow passage extending longitudinally througha riser string, the annular seal module being secured in the flowpassage between opposite end connections of the riser string; thenconveying another annular seal module into the flow passage; and sealingan annular space between the riser string and a tubular string in theflow passage utilizing the multiple annular seal modules.

Another drilling method includes the steps of: installing an annularseal module in an internal flow passage extending longitudinally througha riser string, the annular seal module being secured in the flowpassage between opposite end connections of the riser string; thenconveying on a tubular string at least one seal into the annular sealmodule; and then sealing an annular space between the riser string andthe tubular string in the flow passage utilizing the seal, the sealingstep being performed while a drill bit on the tubular string is rotated.

These and other features, advantages, benefits and objects will becomeapparent to one of ordinary skill in the art upon careful considerationof the detailed description of representative embodiments of theinvention hereinbelow and the accompanying drawings, in which similarelements are indicated in the various figures using the same referencenumbers.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an elevation view of a prior art floating drillinginstallation with a conventional riser system;

FIG. 2 is an elevation view of a prior art floating drillinginstallation in which a slip joint is locked closed and a rotatingcontrol device maintains riser pressure and diverts mud flow throughhoses into a mud pit, with the riser being disconnected from a rigfloor;

FIGS. 3 a-e are schematic elevation views of typical conventional risersystems used for floating drilling installations;

FIG. 3 f is a schematic elevation view of a riser system and methodembodying principles of the present invention as incorporated into thesystem of FIG. 3 a;

FIG. 3 g is a schematic elevation view of an alternate configuration ofa riser system and method embodying principles of the present inventionas incorporated into a DORS (deep ocean riser system);

FIG. 4 is an elevation view of a prior art riser system similar to thesystem of FIG. 3 b, utilizing a surface BOP;

FIG. 5 is an elevation view of a prior art riser system having arotating control device attached to a top of a subsea BOP stack;

FIG. 6 a is a schematic view of fluid flow in a prior art concept ofconventional drilling;

FIG. 6 b is a schematic view of a concept of closed system drillingembodying principles of the present invention;

FIG. 7 is a further detailed schematic elevation view of anotheralternate configuration of a riser system and method embodyingprinciples of the present invention;

FIG. 8 is a schematic cross-sectional view of another alternateconfiguration of a riser system and method embodying principles of thepresent invention;

FIG. 9 is a schematic cross-sectional view of another alternateconfiguration of a riser system and method embodying principles of thepresent invention;

FIG. 10 is a schematic cross-sectional view of a riser injection systemwhich may be used with any riser system and method embodying principlesof the present invention;

FIG. 11 is a process and instrumentation diagram (P&ID) of the risersystem including the riser injection system of FIG. 10;

FIG. 12 is a schematic cross-sectional view of another alternateconfiguration of the riser system and method embodying principles of thepresent invention, showing installation of a valve module in the risersystem;

FIG. 13 is a schematic cross-sectional view of the riser system andmethod of FIG. 12, showing the valve module after installation;

FIG. 14 is a schematic cross-sectional view of the riser system andmethod of FIG. 12, showing installation of an annular seal module in theriser system;

FIG. 15 is a schematic cross-sectional view of the riser system andmethod of FIG. 12, showing the annular seal module after installation;

FIG. 16 is a schematic cross-sectional view of the riser system andmethod of FIG. 12, showing installation of another annular seal modulein the riser system;

FIG. 17 is a schematic cross-sectional view of the riser system andmethod of FIG. 12, showing the annular seal module of FIG. 16 afterinstallation;

FIG. 18 is a schematic cross-sectional view of the riser system andmethod of FIG. 12, showing installation of a riser testing module in theriser system;

FIG. 19 is a schematic cross-sectional view of the riser system andmethod of FIG. 12, showing a configuration of the riser system during ariser pressure testing procedure;

FIG. 20 is a schematic cross-sectional view of the riser system andmethod of FIG. 12, showing conveyance of an annular seal module into theriser system on a drill string;

FIG. 21 is a schematic cross-sectional view of the riser system andmethod of FIG. 12, showing retrieval of an annular seal module from theriser system on a drill string;

FIG. 22 is a schematic cross-sectional view of the riser system andmethod of FIG. 12, showing a configuration of the riser system duringdrilling operations;

FIG. 23 is a schematic cross-sectional view of the riser system andmethod of FIG. 12, showing a riser flange connection, taken along line23-23 of FIG. 18;

FIG. 24 is a schematic elevation view of the riser system and method ofFIG. 12, showing an external valve manifold configuration;

FIG. 25 is a schematic cross-sectional view of the external valvemanifold configuration, taken along line 25-25 of FIG. 24;

FIGS. 26A-E are schematic elevation views of various positions ofelements of the riser system and method of FIG. 12;

FIG. 27 is an isometric view of a riser section of the riser system andmethod of FIG. 12, showing an arrangement of various lines, valves andaccumulator external to the riser;

FIG. 28 is a schematic cross-sectional view of an alternate annular sealmodule for use in the riser system and method of FIG. 12;

FIG. 29 is a schematic cross-sectional view of a method whereby multipleannular seal modules may be installed in the riser system and method ofFIG. 12;

FIG. 30 is a schematic partially cross-sectional view of a methodwhereby multiple modules may be retrieved in the riser system and methodof FIG. 12;

FIG. 31 is a schematic partially cross-sectional view of a methodwhereby various equipment may be installed using the riser system andmethod of FIG. 12;

FIG. 32 is a schematic elevational view of another alternateconfiguration of the riser system.

DETAILED DESCRIPTION

It is to be understood that the various embodiments of the presentinvention described herein may be utilized in various orientations, suchas inclined, inverted, horizontal, vertical, etc., and in variousconfigurations, without departing from the principles of the presentinvention. The embodiments are described merely as examples of usefulapplications of the principles of the invention, which is not limited toany specific details of these embodiments.

In the following description of the representative embodiments of theinvention, directional terms, such as “above”, “below”, “upper”,“lower”, etc., are used for convenience in referring to the accompanyingdrawings. In general, “above”, “upper”, “upward” and similar terms referto a direction toward an upper end of a marine riser, and “below”,“lower”, “downward” and similar terms refer to a direction toward alower end of a marine riser.

In the drawings, and in the description that follows, like parts aremarked throughout the specification and drawings with the same referencenumerals, respectively. The drawing figures are not necessarily toscale. Certain features of the invention may be shown exaggerated inscale or in somewhat schematic form and some details of conventionalelements may not be shown in the interest of clarity and conciseness.

The present invention is susceptible to embodiments of different forms.Specific embodiments are described in detail and are shown in thedrawings, with the understanding that the present disclosure is to beconsidered an exemplification of the principles of the invention, and isnot intended to limit the invention to that illustrated and describedherein. It is to be fully recognized that the different teachings of theembodiments discussed below may be employed separately or in anysuitable combination to produce desired results.

Any use of any form of the terms “connect,” “engage,” “couple,” “attach”or any other term describing an interaction between elements is notmeant to limit the interaction to direct interaction between theelements and may also include indirect interaction between the elementsdescribed. The various characteristics mentioned above, as well as otherfeatures and characteristics described in more detail below, will bereadily apparent to those skilled in the art upon reading the followingdetailed description of the embodiments, and by referring to theaccompanying drawings.

An offshore universal riser system (OURS) 100 is disclosed which isparticularly well suited for drilling deepwater in the floor of theocean using rotatable tubulars. The riser system 100 uses a universalriser section which may be interconnected near a top of a riser stringbelow the slip joint in a subsea riser system. The riser system 100includes: a seal bore to take an inner riser string (if present) with avent for outer riser, a nipple to receive pressure test adapters, aninlet/outlet tied into the riser choke line, kill line or boosterline(s) as required, one or more integral Blow Out Preventers as safetydevices, outlet(s) for pressurized mud return with a valve(s), anoptional outlet for riser overpressure protection, one or more sealbores with adapters that can accept a variety of RCD designs, aprovision for locking said RCD(s) in place, a seal bore adapter to allowall RCD utilities to be transferred from internal to external and viceversa. Externally, the universal riser section includes all the usualriser connections and attachments required for a riser section.Additionally the riser system 100 includes provision for mounting anaccumulator(s), provision for accepting instrumentation for measuringpressure, temperature and any other inputs or outputs, e.g., riser levelindicators; a line(s) taking pressurized mud to the next riser sectionabove or slip joint; Emergency Shut Down system(s) and remote operatedvalve(s); a hydraulic bundle line taking RCD utilities and controls; anelectric bundle line for instrumentation or other electricalrequirements. A choking system may also be inserted in the mud returnline that is capable of being remotely and automatically controlled. Theriser system 100 may also have a second redundant return line ifrequired. As part of the system 100, when desired, an injection system200 including a lower riser section coupled with a composite hose (orother delivery system) for delivery of fluids may be included with aninlet to allow injection of a different density fluid into the riser atany point between the subsea BOP and the top of the riser. This allowsthe injection into the riser of Nitrogen or Aphrons (glass spheres), orfluids of various densities that will allow hydrostatic variations to beapplied to the well, when used in conjunction with a surface or subsurface choke.

There is flexibility in the riser system 100 to be run in conjunctionwith conventional annular pressure control equipment, multiple RCDs,adapted to use with 13⅜ high pressure riser systems or other highpressure riser systems based in principle on the outlines in FIG. 3 b, 3c, or 3 e. Instead of the standard 21 inch riser system, any other sizeof riser system can also be adapted for use with the riser system 100and/or injection system 200 (discussed further below), which can beplaced at any depth in the riser depending on requirements.

A refined and more sensitive control method for MPD (Managed PressureDrilling) will be achieved by the riser system 100 with the introductionof Nitrogen in to the riser below the RCD. This will be for the purposeof smoothing out surges created by the heave of the floating drillinginstallation due to the cushioning effect of the Nitrogen in the riseras well as allowing more time for the choke manipulation to control thebottom hole pressure (BHP) regime. It has been demonstrated on many MPDjobs carried out on non-floating drilling installations, that having asingle phase fluid makes it more difficult to control the BHP with thechoke manipulation. On a floating drilling installation any surge andswab through the RCD has a more direct effect on the BHP with themonophasic system as it is not possible to compensate with the chokesystem. With the riser system 100, the choke(s) can be controlled bothmanually and/or automatically with input from both surface and or bottomhole data acquisition.

The riser system 100 allows Nitrified fluid drilling that is stilloverbalanced to the formation, improved kick detection and control, andthe ability to rotate pipe under pressure during well control events.

This riser system 100 allows a safer installation as there is no changein normal practice when running the riser system and all functionsremain for subsea BOP control, emergency unlatch, fluid circulation, andwell control.

The riser system 100 includes seal bore protector sleeves and runningtool(s) as required, enabling conversion from a standard riser sectionto full riser system 100 use.

The riser system 100 also may include the addition of lines on theexisting slip joint which can be done: (1) permanently with additionallines and gooseneck(s) on slip joint, and hollow pipes for feedingthrough hydraulic or electrical hoses; or (2) temporarily by strappinghoses and bundles to the slip joint if acceptable for environmentalconditions.

A system is disclosed for drilling deepwater in the floor of the oceanusing rotatable tubulars. This consists of the riser system 100 andinjection system 200. The two components can be used together orindependently.

Referring to FIG. 10, the injection system 200 consists of a risersection (usually a shorter section called a pup) which has an inlet, anda composite hose system, of other suitable delivery mechanism to allowinjection of different density fluids into the riser at any pointbetween the subsea BOP and the top of the riser system 100.

The riser system 100 acts as a passive riser section during normaldrilling operations. When pressurized operations are required,components are inserted into it as required to enable its fullfunctionality. The section of riser used for riser system 100 may bemanufactured from a thicker wall thickness of tube.

Referring to FIG. 9, this shows a detailed schematic cross section of anembodiment of a riser system 100. The drawing is split along the centerline CL with the left hand side (lhs) showing typical configuration ofinternal components when in passive mode, and the right hand side (rhs)showing the typical configuration when in active mode. In the drawing,only major components are shown with details like seals, recesses,latching mechanisms, bearings not being illustrated. These details arethe standard type found on typical wellbore installations and componentsthat can be used with the riser system 100. Their exact detail dependson the particular manufacturers' equipment that is adapted for use inthe riser system 100.

As illustrated in FIG. 9, the riser system 100 includes a riser section30 with end connectors 31 and a rotatable tubular 32 shown in typicalposition during the drilling process. This tubular 32 is shown forillustration and does not form part of the riser system 100. The section30 may include a combination of components. For example, the section 30may include an adapter A for enabling an inner riser section to beattached to the riser system 100. This is for the purpose of raising theoverall pressure rating of the riser system being used. For example, a21 inch marine riser system may have a rating of 2000 psi workingpressure. Installing a 9⅝ inch casing riser 36 will allow the riserinternally to be rated to a new higher pressure rating dependent on thecasing used. The riser system 100 section will typically have a higherpressure rating to allow for this option.

The section 30 may also include adapters B1 and B2 for enabling pressuretests of the riser and pressure testing the components installed duringinstallation, operation and trouble shooting.

The section 30 may also include adapters C1, C2, and C3, which allowinsertion of BOP (Blow Out Preventer) components and RCD (RotatingControl Devices). A typical riser system 100 will have at least one RCDdevice installed with a back-up system for safety. This could be asecond RCD, an annular BOP, a Ram BOP, or another device enablingclosure around the rotatable tubular 32. In the configuration shown inFIG. 9, a variety of devices are illustrated to show the principle ofthe riser system 100 being universally adaptable. For example, but notintended to be limiting, C1 is a schematic depiction of an annular BOPshown as an integral part of the riser system 100. It is also possibleto have an annular BOP as a device for insertion. C2 shows schematicallyan active (requires external input to seal) RCD adaptation and C3 showsa typical passive (mechanically sealing all the time) RCD adaptationwith dual seals.

The riser system 100 has several outlets to enable full use of thefunctionality of the devices A, B, and C1-C3. These include outlet 33which allows communication to the annulus between the inner and outerriser (if installed), inlet/outlet 40 which allows communication intothe riser below the safety device installed in C1, outlet 41 which isavailable for use as an emergency vent line if such a system is requiredfor a particular use of the riser system 100, outlet/inlet 44 whichwould be the main flow outlet (can also be used as an inlet forequalization), outlet 45 which can be used to provide a redundant flowoutlet/inlet, outlet 54 which can be used as an alternative outlet/inletand outlet 61 which can be used as an inlet/outlet. The particularconfiguration and use of these inlets and outlets depends on theapplication. For example, in managed pressure drilling, outlets 44 and45 could be used to give two redundant outlets. In the case of mud-capdrilling, outlet 44 would be used as an inlet tied into one pumpingsystem and outlet 45 would be used as a back-up inlet for a secondpumping system. A typical hook-up schematic is illustrated in FIG. 11,which will be described later.

The details for the devices are now given to allow a fullerunderstanding of the typical functionality of the riser system 100. Theriser system 100 is designed to allow insertion of items as required,i.e., the clearances allow access to the lowermost adapter to insertitems as required, with increases in clearance from bottom to top.

Device A is the inner riser adapter and may be specified according tothe provider of the inner riser system. On the lhs (left hand side) item34 is the adapter that would be part of the riser system 100. This wouldhave typically a seal bore and a latch recess. A protector sleeve 35would usually be in place to preserve the seal area. On the rhs (righthand side) the inner riser is shown installed. When the inner riser 36is run, this sleeve 35 would be removed to allow latching of the innerriser 36 in the adapter 34 with the latch and seal mechanism 37. Theexact detail and operation depends on the supplier of the inner riserassembly. Once installed, the inner riser provides a sealed conduiteliminating the pressure weakness of the outer riser section 30. Theriser system 100 may be manufactured to a higher pressure rating so thatit could enable the full or partial pressure capability of the innerriser system. An outlet 33 is provided to allow monitoring of theannulus between inner riser 36 and outer riser 30.

Devices B1 and B2 are pressure test adapters. Normally in conventionaloperations the riser is never pressure tested. All pressure tests takeplace in the subsea BOP stack. For pressurized operations, a pressuretest is required of the full riser system after installation to ensureintegrity. For this pressure test, adapter B2 is required which is thesame in principle as the description here for pressure test adapter B1.The riser system 100 includes an adapter 38 for the purpose of acceptinga pressure test adapter 39. This pressure test adapter 39 allows passageof the maximum clearance required during the pressurized operations. Itcan be pre-installed or installed before pressurized operations arerequired. When a pressure test is required, an adapter 39 a is attachedto a tubular 32 and set in the adapter 39 as illustrated in the rhs ofFIG. 9. The adapter 39 a will lock positively to accept pressure testsfrom above and below. The same description is applicable for device B2,which is installed at the very top of the riser system 100, i.e., abovethe outlet 61. With B2, the whole riser and riser system 100 can bepressure tested to a ‘test’ pressure above subsequent planned pressuretest. Once the overall pressure test is achieved with device B2,subsequent pressure tests will usually use device B1 for re-pressuretesting the integrity of the system after maintenance on RCDs.

Device C1 is a safety device that can be closed around the rotatabletubular 32, for example but not being limited to an annular BOP 42, aram BOP adapted for passage through the rotary table, or an active RCDdevice like that depicted in C2. The device C1 can be installedinternally like C2 and C3 or it can be an integral part of the risersystem 100 as depicted in FIG. 9. Item 42 is a schematic representationof an annular BOP without all the details. When not in use as shown onthe lhs, the seal element is in a relaxed state 43 a. When required, itcan be activated and will seal around the tubular 32 as shown on the rhswith representation 43 b. For particular applications, e.g.,underbalanced flow drilling where hydrocarbons are introduced into theriser under pressure, two devices of type C1 may be installed to providea dual barrier.

Device C2 schematically depicts an active RCD. An adapter 46 is part ofthe riser system 100 to allow installation of an adapter 47 with therequired seal and latch systems that are designed for the particular RCDbeing used in the riser system 100. Both 46 and 47 have ports to allowthe typical supply of hydraulic fluids required for the operation of anactive RCD. A seal protector and hydraulic port isolation and sealprotector sleeve 48 are normally in place when the active RCD 50 is notinstalled as shown on the lhs. When the use of the active RCD 50 isrequired, the seal protector sleeve 48 is pulled out with a running toolattached to the rotatable tubular 32. Then the active RCD 50 isinstalled as shown on the rhs. A hydraulic adapter manifold 51 providescommunication from the hydraulic supply (not shown) to the RCD.Schematically, two hydraulic conduits are shown on the rhs. Conduit 52supplies hydraulic fluid to energize the active element 49 and hydraulicconduit 53 typically supplies oil (or other lubricating fluid) to thebearing. A third conduit may be present (not shown) which allowsrecirculation of the bearing fluid. Depending on the particular type ofactive RCD, more or fewer hydraulic conduits may be required for otherfunctions, e.g., pressure indication and/or latching functions.

Device C3 schematically depicts a passive RCD 58 with two passiveelements 59 and 60 as is commonly used. An adapter 57 is installed inthe riser system 100. It is possible to make adapters that protect thesealing surface by bore variations and in such a case for a passive headrequiring no utilities (some require utilities for bearinglubrication/cooling) no seal protector sleeve is required. In this casethe passive RCD 58 can be installed directly into the adapter 57 asshown on rhs with the sealing elements 59 and 60 continuously in contactwith the tubular 32. This schematic installation also assumes that thelatching mechanism for the RCD 58 is part of the RCD andactivated/deactivated by the running tool(s).

The riser system 100 may also include other items attached to it to makeit a complete package that requires no further installation activityonce installed in the riser. These other items may includeinstrumentation and valves attached to the outlets/inlets 33, 40, 41,44, 45, 54, 61. These are described in conjunction with FIG. 11 below.To enable full functionality of these outlet utilities and of thedevices installed (A, B1, B2, C1, C2, C3) the riser system 100 includesa control system 55 that centralizes all the monitoring activities onthe riser system 100 and provides a data link back to the floatingdrilling installation. The riser system 100 includes another controlsystem 55 that provides for control of hydraulic functions of thevarious devices and an accumulator package 56 that provides the reservepressure for all the hydraulic utilities. Other control/utility/supplyboxes may be added as necessary to minimize the number of connectionsrequired back to surface.

Referring to FIG. 11, this shows the typical flow path through the risersystem 100 and injection system 200. Drilling fluid 81 flows down therotatable tubular 32, exiting at the drilling bit 82. Then the fluid isa mixture of drilling fluid and cuttings that is returning in theannulus between the rotatable tubular and the drilled hole. The flowpasses through a subsea BOP 83 if installed and then progresses into theriser string 84. The injection system 200 can inject variable densityfluid into this return flow. The flow 85 continues as a mixture ofdrilling fluid, cuttings, and variable density fluid introduced by theinjection system 200 up the riser into the riser system 100. There itpasses through the safety devices C1, C2, and C3 and proceeds into theslip joint 91 if none of the devices is closed.

Outlet 41 is connected to a safety device 104 that allows for pressurerelief back to the floating drilling installation through line 95. Thissafety device 104 may be a safety relief valve or other suitable systemfor relieving pressure.

Devices C1, C2, and C3 are connected through their individual controlpods 301, 302, and 303 respectively to a central electro-hydrauliccontrol system 304 that also includes accumulators. It has an electricline 89 and a hydraulic line 90 back to the floating drillinginstallation. In concept, the usage of the different connections issimilar so the following description for items 40, 111, 112, 113, 114,and 119 is the same as for: 44, 118, 117, 115, 116 and 119; and for 45,124, 123, 122, 121 and 120; as well as for 54, 131, 132, 133, 134 and120.

How many of these sets of connections and valves are installed isdependent on the planned operation, number of devices (C1, C2, and C3)installed, and the degree of flexibility required. A similar set ofitems can be connected to outlet 61 if required.

Taking outlet/inlet 40 as a typical example of the above listed sets, aninstrument adapter or sensor 111 which can measure any required data,typically pressure and temperature, is attached to the line from outlet40. The flow then goes through this line via a choking system 112 thatis hydraulically or otherwise controlled, then through two hydraulicallycontrolled valves 113 and 114 of which at least one is fail closed. Theflow can then continue up line 88 back to the floating drillinginstallation. Flow can also be initiated in reverse down this line 88 ifrequired. A similar line 194 is provided connected to outlet/inlet 45.

Sensor 111 can monitor parameters (such as pressure and/or temperature,etc.) in the interior of the riser section 30, riser string 84 or riserstring 206 (described below) below the annular BOP 42 or the valvemodule 202 described below (see FIGS. 12 & 13). Sensors 118, 124 canmonitor parameters (such as pressure and/or temperature, etc.) in theinterior of the riser section 30 or riser string 84 or 206 between theannular BOP 42 or valve module 202 and the active RCD 50 or annular sealmodule 224 (described below, see FIGS. 14 & 15). Sensor 131 can monitorparameters (such as pressure and/or temperature, etc.) in the interiorof the riser section 30 or riser string 84 or 206 between the active RCD50 or annular seal module 224 and the passive RCD 58 or annular sealmodule 222 (described below, see FIGS. 16 & 17). Further or differentsensors may be used to monitor, store and/or transmit data indicative ofany combination of parameters, as desired.

As depicted, FIG. 11 is a typical process and instrumentation diagramand can be interpreted as such, meaning any variation of flow patternsas required can be obtained by opening and closing of valves inaccordance with the required operation of the devices C1, C2, and C3which can be closed or opened (except, for example, the passive RCD 58depicted in FIG. 9, which is normally always closed).

The control systems 55 described above are depicted in further detail inFIG. 11 as control systems 119, 120, 304. These control systems 119,120, 304 are located subsea external to the riser string 84 or 206 andcentralize electrical and hydraulic connections to the subsea valves113, 114, 115, 116, 121, 122, 133, 134, so that fewer electrical andhydraulic lines are needed to the surface.

Control system 119 is connected to electric line 186 and hydraulicsupply line 87 for controlling actuation of valves 113, 114, 115, 116and chokes 112, 117. Control system 119 also receives data signals fromsensors 111, 118. Control signals from the surface may be multiplexed onthe electric line 186, and data signals from the sensors 111, 118 mayalso be multiplexed on the electric line 186.

If outlet 44 is used for return flow of drilling fluids during drilling,then choke 117 may be used to regulate back pressure in the riser string84 for managed pressure drilling to maintain a desired constant orselectively varying downhole pressure (for example, a bottomholepressure at the drill bit depicted in FIG. 6B). The choke 117 may beautomatically controlled via the control system 119 in conjunction witha surface control system 18 (see FIG. 10), for example, to enableautomatic control of the choke without need for human intervention(although human intervention may be provided for, if desired).

Control system 120 is connected to electric line 192 and hydraulicsupply line 93 for controlling actuation of valves 121, 122, 133, 134and chokes 123, 132. Control system 120 also receives data signals fromsensors 124, 131. Control signals from the surface may be multiplexed onthe electric line 192, and data signals from the sensors 124, 131 mayalso be multiplexed on the electric line 192.

If outlet 45 or 54 is used for return flow of drilling fluids duringdrilling, then choke 123 or 132 may be used to regulate back pressure inthe riser string 84 for managed pressure drilling to maintain a desiredconstant or selectively varying downhole pressure (for example, abottomhole pressure at the drill bit depicted in FIG. 6B). The choke 123or 132 may be automatically controlled via the control system 120 inconjunction with a surface control system (not shown), for example, toenable automatic control of the choke without need for humanintervention (although human intervention may be provided for, ifdesired).

Control system 304 is connected to electric line 89 and hydraulic supplyline 90 for controlling operation of the control pods 301, 302, 303. Thecontrol pods 301, 302, 303 include valves, actuators, accumulators,sensors for actuating and monitoring operation of the various modules(e.g., annular BOP 42, active RCD 50, passive RCD 58, valve module 202and/or annular seal modules 222, 224, 226) which may be installed in theriser section 30 or riser string 84 or 206.

Any of the subsea control systems 119, 120, 304 can be replaced by meansof a subsea remotely operated vehicle 320 (see FIG. 30). Thus, in theevent of failure, malfunction, updating or requirement for maintenanceof any of the control systems 119, 120, 304, this can be accomplishedwithout need for disturbing the riser string 84 or 206.

Variable density fluid is injected down conduit 11 to the injectionsystem 200 and the detailed description for this operation is describedmore fully below.

The injection system 200 consists of a riser section (usually a shortersection called a pup) which has an inlet, and a composite hose system,or other suitable delivery mechanism to allow injection of differentdensity fluids into the riser at any point between the subsea BOP andthe top of the riser system 100.

The injection system 200 can be used independently of or in conjunctionwith the riser system 100 on any floating drilling installation toenable density variations in the riser. In managed pressure orunderbalanced drilling operations, the injection system 200 may be usedto inject a fluid composition 150 into the riser string 84 which hasless density than the drilling fluid 81 returned from the wellboreduring drilling.

The injection system 200 allows the injection into the riser of a fluidcomposition 150 including, for example, Nitrogen or Aphrons (hollowglass spheres), or fluids of various densities which will allowhydrostatic variations to be applied to the well, when used inconjunction with a surface or sub surface choke. As describedpreviously, the injection system 200 is a conduit through which aNitrogen cushion could be applied and maintained to allow more controlof the BHP by manipulation of the surface choke, density of fluidinjected, and injection rate both down the drill string and into theannulus through the injection system 200.

The injection system 200 externally includes all the usual riserconnections and attachments required for a riser section. Additionally,the injection system 200 includes provision for mounting anaccumulator(s) (shown), provision for accepting instrumentation formeasuring pressure, temperature, and any other inputs or outputs.Emergency shut down system(s) remote operated valve(s), a hydraulicbundle line supplying hydraulic fluid, hydraulic pressure and controlsignals to the valve, and choke systems may also be included on theinjection system 200.

The injection system 200 may be based solely on a hydraulic system, ahydraulic and electric bundle line for instrumentation or otherelectrical control requirements, or a full MUX (Multiplex) system. Achoking system may also be inserted in the fluid injection conduit(shown) that is remotely and automatically controlled.

A riser section 1, which may be a riser pup, of the same design as theriser system with the same end connections 16 as the riser system is thebasis of the injection system 200. This riser section 1 includes a fluidinjection connection 2 with communication to the inside of the risersection 1. This connection 2 can be isolated from the riser internalfluid by hydraulically actuated valves 3 a and 3 b fitted with hydraulicactuators 4 a and 4 b. The injection rate can be controlled both by asurface control system 19 (pump rate and/or choke) and subsea by aremotely operated choke 14. As added redundancy, one or more non-returnvalve(s) 8 may be included in the design. The conduit to supply theinjection fluid from surface to the injection system 200 is shown as aspoolable composite conduit 11, which can be easily clamped to the riseror subsea BOP guidelines (if water depth allows and they are in place).Composite pipe and spooling systems as supplied by the FibersparCorporation are suitable for this application. The composite conduit 11is supplied on a spoolable reel 12. The composite conduit 11 can beeasily cut and connectors 13 fitted in-situ on the floating drillinginstallation for the required length. The operating hydraulic fluid forthe actuators 4 a and 4 b of subsea control valves 3 a and 3 b andhydraulic choke 14 can be stored on the injection system 200 inaccumulators 5 and 15, respectively. They can be individual, independentaccumulator systems or one common supply system with electronic controlvalves as supplied in a MUX system. The fluid to the accumulators 5, 15is supplied and maintained through hydraulic supply lines 9 fromhydraulic hose reel 10 supplied with hydraulic fluid from a surfacehydraulic supply and surface control system 18. As discussed above, thesurface control system 18 may also be used to control operation ofsubsea control systems 119, 120, 304, although additional or separatesurface control system(s) may be used for this purpose, if desired.

Hydraulic fluid for the valve actuators 3 a and 3 b from the accumulator5 is supplied through hose 7 and hydraulic fluid from accumulator 15 issupplied through hose 17 to hydraulic choke 14. Electro-hydrauliccontrol valve 6 a for actuators 4 a and 4 b allows closing and openingof valves 3 a and 3 b by way of electrical signals from surface suppliedby electric line 20 and electro-hydraulic control valve 6 b allowsclosing and opening of the hydraulic choke 14 similarly supplied bycontrol signal from surface by line 20.

During conventional drilling operations, the valves 3 a and 3 b areclosed and the injection system 200 acts like a standard section ofriser. When variable density operations are required in the riser,valves 3 a and 3 b are opened by hydraulic control and a fluidcomposition 150 including, e.g., Nitrogen is injected by the surfacesystem 19 through the hose reel 12 down the conduit 11 into the riserinlet connection 2. The rate can be controlled at the surface system 19and/or by the downhole choke 14 as required. One of the hydrauliccontrol valves 3 b is set up as a fail-safe valve, meaning that ifpressure is lost in the hydraulic supply line it will close, thus alwaysensuring the integrity of the riser system. Similarly, when a return toconventional operations is required, fluid injection is stopped and thevalves 3 a and 3 b are closed.

The injection system 200 may include, as illustrated in FIG. 11,pressure and temperature sensors 21, plus the required connections andsystems going to a central control box 142 (see FIG. 11) to transmitthese to surface. The valves 3 a, 3 b and choke 14 may be operated byhydraulic or electric signal and cables 9, 20 run with the reel 10 or byacoustic signal or other system enabling remote control from surface.

In FIG. 11 the variable density fluid composition 150 is injected downthe conduit 11, through a non-return valve 8, two hydraulic remotecontrolled valves 3 a and 3 b, then through a remote controlled choke 14into inlet 2. Sensors 21 allow the measurement of desired data which isthen routed to the control system 142 which consists of controls,accumulators which receives input/output signals from line 20 andhydraulic fluid from line 9.

An example use and operating procedure are described here for a typicalfloating drilling installation to illustrate an example method of use ofthe system.

The riser system 100 will be run as a normal section of riser throughthe rotary table RT, thus not exceeding the normal maximum OD for a 21inch riser system of about 49 inches or 60 inches as found on newergeneration floating drilling installations. It will have full borecapability for 18¾ inch BOP stack systems and be designed to the samespecification mechanically and pressure capability as the heaviest wallsection riser in use for that system. An injection system 200 will berun in the lower part of the riser with spoolable composite pipe(FIBERSPAR™, a commercially available composite pipe, is suitable forthis application).

In normal drilling operations with, e.g., a plan to proceed to managedpressure drilling, the riser system 100 and injection system 200 will berun with all of the external components installed. The riser system 100and injection system 200 will be installed with seal bore protectorsleeves 35, 48 in place and pressure tested before insertion into riser.During conventional drilling operation the inlet and outlet valves willbe closed and both the riser system 100 and injection system 200 willact as normal riser pup joints. The riser system 100 will be preparedwith the correct seal bore adapters for the RCD system to be used.

When pressurized operations are required, the injection system 200 isprepared and run as part of the riser inserted at the point required.The necessary connections for control lines 9, 20 are run, as well asthe flexible conduit 11, for injecting fluids of variable density in thefluid composition 150. The cables and lines are attached to the riser orto the BOP guidelines if present. Valves 3 a and 3 b are closed.

The riser system 100 is prepared with the necessary valves and controlsas shown in FIG. 11. All the valves are closed. The hoses and lines areconnected as necessary and brought back to the floating drillinginstallation.

Pipe will be run in hole with a BOP test adapter. The test adapter isset in the subsea wellhead and the annular BOP C3 is closed in the risersystem 100. A pressure test is then performed to riser working pressure.The annular BOP C3 in the riser system 100 is then opened and thepressure test string is pulled out. If the subsea BOP has rams that canhold pressure from above, a simpler test string can be run setting atest plug in adapter B2 on the riser system 100 (see FIG. 9).

When the riser system 100 is required for use, an adapter 39 will be runin the lower nipple B1 of the riser system 100 to provide a pressuretest nipple similar to that of the smallest casing string in thewellhead so that subsequent pressure tests do not require a trip tosubsea BOP.

The seal bore protector sleeve 48 for the RCD adapter C2 may be pulledout. Then the RCD 50 can be set in C2. Once set, the RCD 50 is functiontested.

The rotatable tubular 32 is then run in hole with the pressure testadapter 39 a for the riser system 100 until the adapter 39 a is set inadapter 39 (already prepared as part of a previous step). The RCD 50 isthen closed and, for active systems only, fluid is circulated throughthe riser system 100 using, e.g., outlet 44. The outlet 44 is thenclosed and the riser is pressure tested. Once pressure tested, thepressure is bled off and the seal element on the RCD 50 is released. Thetest assembly is then pulled out of the riser system 100. A similarmethod may be completed to set another RCD 58 in section C3.

The drilling assembly is then run in hole and circulation at thedrilling depth is established. The pumps are then stopped. Once stopped,the RCD 50 seal element is installed (only if needed for the particulartype of RCD), and the RCD 50 is activated (for active systems only). Themud outlet 44 on the riser system 100 is then opened. Circulation isthen established and backpressure is set with an automated surface chokesystem or, alternatively, the choke 112 connected to the outlet 44. If achange in density is required in the riser fluid, choke 14 (see FIG. 11)is closed on the injection system 200 and valves 3 a, 3 b are opened. Afluid composition 150, including, but not limited to, Nitrogen iscirculated at the desired rate into return flow to establish a cushionfor dampening pressure spikes. It should be appreciated that Nitrogen isonly an example, and that other suitable fluids may be used. Forexample, a fluid composition 150 containing compressible agents (e.g.,solids or fluids whose volume varies significantly with pressure) may beinjected into the riser at an optimum point in order to provide thisdamping. Drilling is then resumed.

The system is shown in FIG. 3 f and depicted schematically in FIG. 6 bfor comparison to the conventional system of FIG. 6 a. A typicalpreferred embodiment for the drilling operation using this inventionwould be the introduction of Nitrogen under pressure into the returndrilling fluid flow stream coming up the riser. This is achieved by thepresently described invention by the injection system 200 with anattached pipe that can be easily run as part of any of the systemsdepicted in FIGS. 3 a-g.

Variations of the above method with the riser system 100 and injectionsystem 200 will enable a variety of drilling permutations that requirepressurized riser operations, such as but not limited to dual density ordual gradient drilling; managed pressure drilling (both under andoverbalanced mud weights); underbalanced drilling with flow from theformation into the wellbore; mud-cap drilling, i.e., injection drillingwith no or little return of fluids; and constant bottom hole pressuredrilling using systems that allow continuous circulation. The risersystem 100/injection system 200 enables the use of DAPC (dynamic annularpressure control) and SECURE (mass balance drilling) systems andtechniques. The riser system 100/injection system 200 also enables theuse of pressurized riser systems with surface BOP systems run below thewater line. The riser system 100/injection system 200 can also be usedto enable the DORS (deep ocean riser system). The ability to introduceNitrogen as a dampening fluid will for the first time give a mechanismfor removing or very much reducing the pressure spikes (surge and swab)caused by heave on floating drilling installations. The riser system100/injection system 200 enables a line into the interior of any of theriser systems depicted in FIGS. 3 a-g and allows the placement of thisline at any point between the surface and bottom of the riser. The risersystem 100 and injection system 200 can be used without a SBOP, thussubstantially reducing costs and enabling the technology shown in FIG. 3g. The riser system depicted in FIG. 3 g also illustrates moving theinjection system 200 to a higher point in the riser.

As described above, the riser system 100 and injection system 200 may beinterconnected into an otherwise conventional riser string. The risersystem 100/injection system 200 provides a means for pressurizing themarine riser to its maximum pressure capability and easily allowsvariation of the fluid density in the riser. The injection system 200includes a riser pup joint with provision for injecting a fluid into theriser with isolation valves. The riser system 100 includes a riser pupjoint with an inner riser adapter, a pressure test nipple, a safetydevice, outlets with valves for diverting the mud flow and nipples withseal bores for accepting RCDs. The easy delivery of fluids to the lowerinjection pup joint (injection system 200) is described. A method isdetailed to manipulate the density in the riser to provide a wide rangeof operating pressures and densities enabling the concepts of managedpressure drilling, dual density drilling or dual gradient drilling, andunderbalanced drilling.

Referring additionally now to FIGS. 12-31, an alternate configuration ofthe riser system 100 is schematically and representatively illustrated.The riser system 100 of FIGS. 12-31 includes many elements which aresimilar in many respects to those described above, or which arealternatives to the elements described above.

In FIGS. 12 & 13, installation of a valve module 202 in a riser string206 is representatively illustrated. FIG. 12 depicts the valve module202 being conveyed and positioned in a valve module housing 280 of theriser string 206, and FIG. 13 depicts the valve module 202 after it hasbeen secured and sealed within the housing 280.

The housing 280 is shown as being a separate component of the riserstring 206, but in other embodiments the housing could be integratedwith other module housings 268, 282, 284, 306 (described below), andcould be similar to the construction of the riser section 30 shown inFIGS. 8 & 9. The riser string 206 could correspond to the riser string84 in the process and instrumentation diagram of FIG. 11.

The housing 280 provides a location 240 for appropriately positioningthe valve module 202 in the riser string 206. In this example, thehousing 280 includes an internal latch profile 262 and a seal bore 328for securing and sealing the valve module 202 in the riser string 206.

The valve module 202 includes an anchoring device 208 with radiallyoutwardly extendable latch members 254 for engaging the profile 262, andseals 344 for sealing in the seal bore 328. The valve module 202 isdepicted in FIG. 13 after the members 254 have been extended intoengagement with the profile 262, and the seals 344 are sealingly engagedwith the seal bore 328.

Other configurations of the valve module 202 can be used, if desired.For example, as depicted in FIGS. 30 & 31, the latch members 254 couldinstead be displaced by means of actuators 278 positioned external tothe riser string 206, in order to selectively engage the latch memberswith an external profile 270 formed on the valve module 202. Operationof the actuators 278 could be controlled by the subsea control systems119, 304, control pod 301 and/or surface control system 18 describedabove.

The valve module 202 selectively permits and prevents fluid flow througha flow passage 204 formed longitudinally through the riser string 206.As depicted in FIGS. 12 & 13, the valve module 202 includes a ball valvewhich is operated by means of a hydraulic control line 316 externallyconnected to the housing 280, but other types of valve mechanisms (suchas flapper valves, solenoid operated valves, etc.) may be used, ifdesired. Operation of the valve module 202 (for example, to open orclose the valve) may be controlled by the subsea control system 304 andcontrol pod 301, and/or the surface control system 18 described above.

A variety of operations may be performed utilizing the valve module 202.For example, the valve module 202 may be used to pressure test variousportions of the riser string 206, to pressure test the annular sealmodules 222, 224, 226 (described below), to facilitate pressure controlin a wellbore 346 during underbalanced or managed pressure drilling(such as, during drill bit 348 changes, etc., see FIG. 22), or duringinstallation of completion equipment 350 (see FIG. 31).

Referring now to FIGS. 14 & 15, an annular seal module 224 isrepresentatively illustrated being installed in a housing 284 in theriser string 206. In FIG. 14, the annular seal module 224 is beingconveyed into the housing 284, and in FIG. 15, the annular seal moduleis depicted after having been secured and sealed within the housing.

The housing 284 provides a location 244 for appropriately positioningthe annular seal module 224 in the riser string 206. In this example,the housing 284 includes an internal latch profile 266 and a seal bore332 for securing and sealing the annular seal module 224 in the riserstring 206. The housing 284 may be a separate component of the riserstring 206, or it may be integrally formed with any other housing(s),section(s) or portion(s) of the riser string.

The annular seal module 224 includes an anchoring device 250 withradially outwardly extendable latch members 258 for engaging the profile266, and seals 352 for sealing in the seal bore 332. The annular sealmodule 224 is depicted in FIG. 15 after the members 258 have beenextended into engagement with the profile 266, and the seals 352 aresealingly engaged with the seal bore 332.

Other configurations of the annular seal module 224 can be used, ifdesired. For example, as depicted in FIGS. 30 & 31, the latch members258 could instead be displaced by means of actuators 278 positionedexternal to the riser string 206, in order to selectively engage thelatch members with an external profile 274 formed on the annular sealmodule 224. Operation of the actuators 278 could be controlled by thesubsea control system 119, 304 and control pod 302, and/or surfacecontrol system 18 described above.

The annular seal module 224 selectively permits and prevents fluid flowthrough an annular space 228 formed radially between the riser string206 and a tubular string 212 positioned in the flow passage 204 (seeFIG. 22). As depicted in FIGS. 14 & 15, the annular seal module 224includes a radially extendable seal 218 which is operated in response topressure applied to a hydraulic control line 318 externally connected tothe housing 284.

The annular seal module 224 also includes a bearing assembly 324 whichpermits the seal 218 to rotate with the tubular string 212 when the sealis engaged with the tubular string and the tubular string is rotatedwithin the flow passage 204 (such as, during drilling operations). Thebearing assembly 324 is supplied with lubricant via a lubricant supplyline 322 externally connected to the housing 284. A lubricant returnline 326 (see FIG. 23) may be used, if desired, to provide forcirculation of lubricant to and from the bearing assembly 324.

The annular seal module 224 is an alternative for, and may be used inplace of, the active RCD 50 described above. Operation of the annularseal module 224 (for example, to extend or retract the seal 218) may becontrolled by means of the subsea control system 304 and control pod302, and/or the surface control system 18 described above.

Referring now to FIGS. 16 & 17, an annular seal module 222 isrepresentatively illustrated being installed in a housing 282 in theriser string 206. In FIG. 16, the annular seal module 222 is beingconveyed into the housing 282, and in FIG. 17, the annular seal moduleis depicted after having been secured and sealed within the housing.

The housing 282 provides a location 242 for appropriately positioningthe annular seal module 222 in the riser string 206. In this example,the housing 282 includes an internal latch profile 266 and a seal bore330 for securing and sealing the annular seal module 222 in the riserstring 206. The housing 282 may be a separate component of the riserstring 206, or it may be integrally formed with any other housing(s),section(s) or portion(s) of the riser string.

The annular seal module 222 includes an anchoring device 248 withradially outwardly extendable latch members 256 for engaging the profile266, and seals 354 for sealing in the seal bore 330. The annular sealmodule 222 is depicted in FIG. 17 after the members 256 have beenextended into engagement with the profile 266, and the seals 354 aresealingly engaged with the seal bore 330.

Other configurations of the annular seal module 222 can be used, ifdesired. For example, as depicted in FIGS. 30 & 31, the latch members256 could instead be displaced by means of actuators 278 positionedexternal to the riser string 206, in order to selectively engage thelatch members with an external profile 272 formed on the annular sealmodule 222. Operation of the actuators 278 could be controlled by thesubsea control system 120, 304 and control pod 303, and/or surfacecontrol system 18 described above.

The annular seal module 222 selectively permits and prevents fluid flowthrough the annular space 228 formed radially between the riser string206 and the tubular string 212 positioned in the flow passage 204 (seeFIG. 22). As depicted in FIGS. 16 & 17, the annular seal module 222includes flexible seals 216 which are for sealingly engaging the tubularstring 212.

The annular seal module 222 also includes a bearing assembly 324 whichpermits the seals 216 to rotate with the tubular string 212 when theseal is engaged with the tubular string and the tubular string isrotated within the flow passage 204 (such as, during drillingoperations). The bearing assembly 324 may be supplied with lubricant viaa lubricant supply line and lubricant return line as described above forthe annular seal module 224.

The annular seal module 222 is an alternative for, and may be used inplace of, the passive RCD 58 described above. Operation of the annularseal module 222 may be controlled by means of the subsea control system304 and control pod 302, and/or the surface control system 18 describedabove.

Referring now to FIG. 18, a tubular string anchoring device 210 isdepicted as installed in a housing 268 interconnected in the riserstring 206. The anchoring device 210 includes latch members 356 engagedwith an internal profile 358 formed in the housing 268. In addition,seals 214 are sealed in a seal bore 360 formed in the housing 268.

The housing 268 may be a separate component of the riser string 206, orit may be integrally formed with any other housing(s), section(s) orportion(s) of the riser string. In this configuration of the risersystem 100, the housing 268 is preferably positioned above the locations240, 242, 244, 246 provided for the other modules 202, 222, 224, 226, sothat the anchoring device 210 and seals 214 may be used for pressuretesting the riser string 206 and the other modules.

In one pressure testing procedure, the anchoring device 210 and seals214 can be conveyed into and installed in the riser string 206 with aportion of the tubular string 212 which extends downwardly from theanchoring device and through any annular seal modules 222, 224, 226, butnot through the valve module 202. This configuration is representativelyillustrated in FIG. 19.

Note that, in FIG. 19, the tubular string 212 extends downwardly fromthe anchoring device 210 (not visible in FIG. 19), through the annularseal modules 222, 224, and into the flow passage 204 above the valvemodule 202. The tubular string 212 does not extend through the valvemodule 202.

The anchoring device 210 functions in the pressure testing procedure toprevent displacement of the tubular string 212 when pressuredifferentials are applied across the annular seal modules 222, 224, 226and the valve module 202. The seals 214 on the anchoring device 210 alsofunction to seal off the flow passage 204. Pressure can be deliveredfrom a remote location (such as a surface facility) through the tubularstring 212 to the flow passage 204 below the anchoring device 210.

The valve module 202 can be pressure tested by applying a pressuredifferential across the closed valve module using the tubular string212. In the configuration of FIG. 19, pressure may be applied via thetubular string 212 to a portion of the riser string 206 between theclosed valve module 202 and the annular seal module 224 (in which theseal 218 has been actuated to sealingly engage the tubular string). Thisapplied pressure would also cause application of a pressure differentialacross the annular seal module 224 and the portion of the riser string206 between the closed valve module 202 and the annular seal module 224.Any pressure leakage observed would be indicative of a structural orseal failure in the valve module 202, riser string 206 portion orannular seal module 224.

In order to pressure test the annular seal module 222 and the portion ofthe riser string 206 between the annular seal modules 222, 224, the seal218 of the annular seal module 224 can be operated to disengage from thetubular string 212. In this manner, pressure applied via the tubularstring 212 to the flow passage 204 would cause a pressure differentialto be applied across the annular seal module 222 and the portion of theriser string 206 between the annular seal modules 222, 224.

Alternatively, or in addition, the tubular string 212 could bepositioned so that its lower end is between the annular seal modules222, 224, in which case operation of the seal 218 may not affect whethera pressure differential is applied across the annular seal module 222 orthe portion of the riser string 206 between the annular seal modules222, 224.

If the valve module 202 is opened, then pressure applied via the tubularstring 212 can be used to pressure test the portion of the riser string206 below the annular seal module 222 and/or annular seal module 224. Inthis manner, the pressure integrity of the portion of the riser string206 which would be subject to significant pressure differentials duringunderbalanced or managed pressure drilling can be verified.

Note that the pressure applied to the flow passage 204 via the tubularstring 212 may be a pressure increase or a pressure decrease, asdesired. In addition, the pressure differentials caused as a result ofthe application of pressure via the tubular string 212 may also be usedfor pressure testing various components of the riser string 206,including but not limited to valves, lines, accumulators, chokes, seals,control systems, sensors, etc. which are associated with the riserstring.

Although the FIG. 19 configuration depicts the annular seal module 222being positioned below the anchoring device 210, the annular seal module224 being positioned below the annular seal module 222, and the valvemodule 202 being positioned below the annular seal module 224, it shouldbe clearly understood that various arrangements of these components, anddifferent combinations of these and other components, may be used inkeeping with the principles of the invention. For example, instead ofone each of the annular seal modules 222, 224 being used in the risersystem 100, only one annular seal module 222 or 224 could be used, twoannular seal modules 222 or two annular seal modules 224 could be used,the annular seal module 226 (described below) could be used in place ofeither or both of the annular seal modules 222, 224, any number orcombination of annular seal modules could be used, the annular BOP 42described above could be used in place of any of the annular sealmodules 222, 224, 226, etc.

Referring additionally now to FIG. 20, the annular seal module 222 isdepicted as being installed in the riser string 206 conveyed on thetubular string 212. The drill bit 348 on the lower end of the tubularstring 212 prevents the annular seal module 222 from falling off of thelower end of the tubular string.

Preferably, the latch members 256 and profile 264 are of the type whichselectively engage with each other as the module 222 displaces throughthe riser string 206. That is, the latch members 256 and profile 264 maybe “keyed” to each other, so that the latch members 256 will notoperatively engage any other profiles (such as profiles 262, 266, 358)in the riser string 206, and the profile 264 will not be operativelyengaged by any other latch members (such as latch members 254, 258,356). A suitable “keying” system for this purpose is the SELECT-20™system marketed by Halliburton Engineering Services, Inc. of Houston,Tex. USA.

One advantage of using such a “keyed” system is that a minimum internaldimension ID of the riser string 206 at each of the module locations240, 242, 244, 246 can be at least as great as a minimum internaldimension of the riser string between the opposite end connections 232,234 of the riser string. This would not necessarily be the case ifprogressively decreasing no-go diameters were used to locate the modules202, 222, 224, 226 in the riser string 206.

Once the annular seal module 222 has been installed in the riser string206, either conveyed on the tubular string 212 as depicted in FIG. 20 orby using a running tool as depicted in FIG. 16, the seals 216 can beinstalled in the annular seal module or retrieved from the annularmodule by conveying the seals on the tubular string 212.

Latch members 257 permit the seals 216 to be separately installed in orretrieved from the annular seal module 222. The latch members 257 could,for example, be the same as or similar to the latch members 256 used tosecure the annular seal module 222 in the riser string 206.

In one preferred method, the annular seal module 222 can be installedand secured in the riser string 206 using a running tool, without theseals 216 being present in the module. Then, when the tubular string 212with the bit 348 thereon is lowered through the riser string 206, theseals 216 can be conveyed on the tubular string and installed andsecured in the annular seal module 222. When the tubular string 212 andbit 348 are retrieved from the riser string 206, the seals 216 can beretrieved also.

This method can also be used for installing and retrieving the seals218, 220 on any of the other annular seal modules 224, 226 describedherein, for example, by providing latch members or other anchoringdevices for the seals in the annular seal modules. The seals 216, 218,220 could also be separately conveyed, installed and/or retrieved onother types of conveyances, such as running tools, testing tools, othertubular strings, etc.

The annular seal modules 222, 224 and/or 226 can be installed in anyorder and in any combination, and the seals 216, 218 and/or 220 can beseparately installed and/or retrieved from the riser string in any orderand in any combination. For example, two annular seal modules (such asthe annular seal modules 222, 224 as depicted in FIG. 21) could beinstalled in the riser string 206, and then the seals 216, 218 could beconveyed on the tubular string 212 (either together or separately) andsecured in the respective annular seal modules. The use of selectivelatch members 257 permits the appropriate seal 216 or 218 to beselectively installed in its respective annular seal module 222, 224.

Referring additionally now to FIG. 21, the annular seal module 222 isdepicted as being retrieved from the riser string 206 by the tubularstring 212. With the latch members 256 disengaged from the profile 264,the annular seal module 222 can be retrieved from within the riserstring 206 along with the tubular string 212 (for example, with thedrill bit 348 preventing the annular seal module from falling off of thelower end of the tubular string), so that a separate trip does not needto be made to retrieve the annular seal module. This method will alsopermit convenient replacement of the seals 216, or other maintenance tobe performed on the annular seal module 222, between trips of thetubular string 212 into the well (such as, during replacement of the bit348).

Note that any of the other modules 202, 224, 226 can also be conveyedinto the riser string 206 on the tubular string 212, and any of theother modules can also be retrieved from the riser string on the tubularstring. In one example described below (see FIG. 30), multiple modulescan be retrieved from the riser string 206 simultaneously on the tubularstring 212.

Referring additionally now to FIG. 22, the riser system 100 isrepresentatively illustrated while the tubular string 212 is rotated inthe flow passage 204 of the riser string 206 in order to drill thewellbore 346 during a drilling operation. The seals 216 of the annularseal module 222 sealingly engage and rotate with the tubular string 212,and the seal 218 of the annular seal module 224 sealingly engage androtate with the tubular string, in order to seal off the annular space228. In this respect, the annular seal module 222 may act as a backupfor the annular seal module 224.

The drilling fluid return line 342 is in this example in fluidcommunication with the flow passage 204 below the annular seal module224. Drilling fluid which is circulated down the tubular string 212 isreturned (along with cuttings, the fluid composition 150 and/orformation fluids, etc., during the drilling operation) via the line 342to the surface.

The line 342 may correspond to the line 88 or 194 described above, andvarious valves (e.g., valves 113, 114, 115, 116, 121, 122, 133, 134),chokes (e.g., chokes 112, 117, 123, 132), sensors (e.g., sensors 111,118, 124, 131), etc., may be connected to the line 342 for regulatingfluid flow through the line, regulating back pressure applied to theflow passage 204 to maintain a constant or selectively varying pressurein the wellbore 346, etc. The line 342 is depicted in FIG. 21 as beingconnected to the portion of the riser string 206 between the annularseal modules 222, 224 in order to demonstrate that various locations forlocating the line may be used in keeping with the principles of theinvention.

Another line 362 may be in fluid communication with the flow passage204, for example, in communication with the annular space 228 betweenthe annular seal modules 222, 224. This line 362 may be used forpressure relief (in which case the line may correspond to the line 95described above), for monitoring pressure in the annular space 228, asan alternate drilling fluid return line, or for any other purpose. Theline 362 could be in communication with the flow passage 204 at anydesired point along the riser string 206, as desired.

Referring additionally now to FIG. 23, an example of a flange connectionalong the riser string 206 is representatively illustrated, in order todemonstrate how the various lines can be accommodated while stillallowing the riser system to fit through a conventional rotary table RT.This view is taken along line 23-23 of FIG. 18. Note that the boosterline BL, choke line CL, kill line KL, well control umbilical 180 andsubsea BOP hydraulic supply lines 364 are conventional and, thus, arenot described further here.

The drilling fluid return line 342 is conveniently installed in atypically unused portion of the flange connection. The injection conduit11 and hydraulic supply line 9, as well as the lubrication supply andreturn lines 322, 326, pressure relief line 362 and electrical lines 20,89, 186, 192 are positioned external to the flange connection, but stillwithin an envelope which permits the riser string 206 to be installedthrough the rotary table RT. A hydraulic return or balance line 182 mayalso be provided external to the flange connection, if desired.

Referring additionally now to FIGS. 24 & 25, a manner in which compactexternal connections to the flow passage 204 in the riser string 206 canbe accomplished is representatively illustrated. In this example,multiple connections are made between the drilling fluid return line 342and the flow passage 204, but it should be understood that suchconnections may be made between the flow passage and any one or moreexternal lines, such as the pressure relief line 362, injection conduit11, etc.

Note that three combined valves 310 and actuators 314 are interconnectedbetween the return line 342 and respective angled riser port connectors366. These valves 310 and actuators 314 may correspond to the variousvalves (e.g., valves 113, 114, 115, 116, 121, 122, 133, 134) and chokes(e.g., chokes 112, 117, 123, 132) described above. By arranging thevalves 310 and actuators 314 as depicted in FIGS. 24 & 25, the riserstring 206 is made more compact and able to displace through aconventional rotary table RT.

Referring additionally now to FIGS. 26A-E, various arrangements of thecomponents of the riser system 100 are representatively illustrated, sothat it may be appreciated that the invention is not limited to anyspecific example described herein.

In FIG. 26A, all of the module housings 268, 306, 282, 284, 280 arecontiguously connected near an upper end of the riser string 206. Thisarrangement has the benefits of requiring shorter hydraulic andelectrical lines for connection to the surface, and permits the housings268, 306, 282, 284, 280 to be integrally constructed as a single sectionof the riser string and to share components (such as accumulators,etc.). However, a large portion of the riser string 206 below thehousings 268, 306, 282, 284, 280 would be pressurized during, forexample, managed pressure drilling, and this may be undesirable in somecircumstances.

In FIG. 26B, the housings 280, 282, 284 for the valve module 202 andannular seal modules 222, 224 are positioned approximately midway alongthe riser string 206. This reduces the portion of the riser string 206which may be pressurized, but increases the length of hydraulic andelectrical lines to these modules.

In FIG. 26C, the housings 268, 306, 282, 284, 280 are distributed alongthe riser string 206 in another manner which places the valve modulehousing 280 just above a flex joint FJ at a lower end connection 234 ofthe riser string to the subsea wellhead structure 236. This arrangementallows the valve module 202 to be used to isolate substantially all ofthe riser string 206 from the well below.

In FIG. 26D, the housings 268, 306, 282, 284, 280 are arrangedcontiguous to each other just above the flex joint FJ. As with theconfiguration of FIG. 26C, this arrangement allows the valve module 202to be used to isolate substantially all of the riser string 206 from thewell below, and also substantially reduces the portion of the riserstring which would be pressurized during managed pressure drilling.

The arrangement of FIG. 26E is very similar to the arrangement of FIG.26D, except that the flex joint FJ is positioned above the housings 268,306, 282, 284, 280. This arrangement may be beneficial in that it doesnot require pressurizing of the flex joint FJ during managed pressuredrilling.

The flex joint FJ could alternatively be positioned between any of thehousings 268, 306, 282, 284, 280, and at any point along the riserstring 206. One advantage of the riser system 100 is that it enablesutilization of a pressurized riser in deepwater drilling operationswhere an intermediate flex joint FJ is required, and where a riser fillup valve is required.

Although each of the housings 306, 282, 284 for the annular seal modules226, 224, 222 are depicted in FIGS. 26A-E, it should be understood thatany one or combination of the housings could be used instead. Thevarious housings 268, 306, 282, 284, 280 may also be arranged in adifferent order from that depicted in FIGS. 26A-E.

Referring additionally now to FIG. 27, a portion 308 of the riser string206 is representatively illustrated in an isometric view, so that thecompact construction of the riser string, which enables it to beinstalled through a conventional rotary table RT, may be more fullyappreciated.

In this view, the externally connected valves 310, actuators 314 andconnectors 366 described above in conjunction with FIGS. 24 & 25 areagain depicted. In addition, an accumulator 312 is shown externallyattached to the riser portion 308. This accumulator 312 may correspondto any of the accumulators 5, 15, 56 described above.

Referring additionally now to FIG. 28, the annular seal module 226 isrepresentatively illustrated as being installed within a seal bore 334in a housing 306 as part of the riser string 206. The annular sealmodule 226 may be used in addition to, or in place of, any of the otherannular seal modules 222, 224, the active RCD 50 or the passive RCD 58described above.

The annular seal module 226 includes multiple sets of seals 220 forsealingly engaging the tubular string 212 while the tubular stringrotates within the flow passage 204. The seals 220 can, thus, seal offthe annular space 228 both while the tubular string 212 rotates andwhile the tubular string does not rotate in the flow passage 204.

In contrast to the seals of the other annular seal modules 222, 224, theactive RCD 50 and the passive RCD 58 which rotate with the tubularstring 212, the seals 220 of the annular seal module 226 do not rotatewith the tubular string. Instead, the seals 220 remain stationary whilethe tubular string 212 rotates within the seals.

A lubricant/sealant (such as viscous grease, etc.) may be injectedbetween the seals 220 via ports 368 from an exterior of the riser string206 to thereby provide lubrication to reduce friction between the sealsand the tubular string 212, and to enhance the differential pressuresealing capability of the seals. Sensors 340 may be used to monitor theperformance of the seals 220 (e.g., to detect whether any leakageoccurs, etc.).

Seals similar in some respects to the seals 220 of the annular sealmodule 226 are described in further detail in PCT Publication No. WO2007/008085. The entire disclosure of this publication is incorporatedherein by this reference.

Although three sets of the seals 220 are depicted in FIG. 28, with threeseals in each set, any number of seals and any number of sets of sealsmay be used in keeping with the principles of the invention.

Anchoring devices 252 are used for securing the annular seal module 226in the housing 306 at the appropriate location 246. Each anchoringdevice 252 includes an actuator 278 and a latch member 260 forengagement with an external profile 276 formed on the annular sealmodule 226.

The use of the actuators 278 external to the riser string 206 providesfor convenient securing and releasing of the module 226 from a remotelocation. In one embodiment, one or more of the modules 226 can beconveniently installed and/or retrieved on the tubular string 212 withappropriate operation of the actuators 278.

Operation of the actuators 278 could be controlled by the subsea controlsystem 120, 304 and control pod 302 or 303, and/or surface controlsystem 18 described above. Operation of the annular seal module 226(e.g., injection of the lubricant/sealant, monitoring of the sensors340, etc.) may be controlled by means of the subsea control system 304and control pod 302 or 303, and/or the surface control system 18described above.

Referring additionally now to FIG. 29, an example of the riser system100 is representatively illustrated in which multiple annular sealmodules 226 are installed in the riser string 206. As depicted in FIG.29, a second upper annular seal module 226 is being conveyed into theriser string 206 on the tubular string 212. The upper module 226 issupported on the tubular string 212 by a radially enlarged (externallyupset) joint 370. When the upper module 226 is appropriately positionedin the housing 306, the actuators 278 will be operated to secure theupper module in position.

It will be appreciated that this method allows for installation of oneor more annular seal modules 226 using the tubular string 212, withoutrequiring additional trips into the riser string 206, and/or duringnormal drilling operations. For example, if during a drilling operationit is observed that the seals 220 of a lower module 226 are at or nearthe end of their projected life (perhaps informed by indicationsreceived from the sensors 340), an additional module 226 can be conveyedby the tubular string 212 into the riser string 206 by merely installingthe module onto the tubular string when a next joint 370 is connected.

In this manner, the drilling operations are not interrupted, and thetubular string 212 does not have to be retrieved from the riser string206, in order to ensure continued sealing of the annular space 228. Thismethod is not limited to use with drilling operations, but can be usedduring other operations as well, such as completion or stimulationoperations.

Referring additionally now to FIG. 30, the riser system 100 isrepresentatively illustrated with multiple modules 202, 222, 224 beingretrieved simultaneously from the riser string 206 on the tubular string212. Use of the external actuators 278 is particularly beneficial inthis example, since they permit all of the modules 202, 222, 224 to bequickly and conveniently released from the riser string 206 forretrieval.

As depicted in FIG. 30, the drill bit 348 supports the modules 202, 222,224 on the tubular string 212 for retrieval from the riser string 206.However, other means of supporting the modules 202, 222, 224 on thetubular string 212 may be used, if desired.

In an emergency situation, such as in severe weather conditions, it maybe desirable to retrieve the tubular string 212 quickly and installhang-off tools. Use of the external actuators 278 enables this operationto be accomplished quickly and conveniently.

In the event of failure of one or more of the actuators 278 to functionproperly, a conventional subsea remotely operated vehicle (ROV) 320 maybe used to operate the actuators 278. As described above, the ROV 320may also be used to perform maintenance on the subsea control systems119, 120, 142, 304, and to perform other tasks.

Also shown in FIG. 30 are sensors 230, 336, 338 of the respectivemodules 202, 222, 224. The sensors 230, 336, 338 can be used to monitorparameters such as pressure, temperature, or other characteristics whichare indicative of the performance of each module 202, 222, 224. Externalconnectors 372 may be used to connect the sensors 230, 336, 338 to thecontrol systems 304, 18.

Referring additionally now to FIG. 31, the riser system 100 isrepresentatively illustrated during installation of completion equipment350 through the riser string 206. Since the modules 202, 222, 224provide for relatively large bore access through the riser string 206,many items of completion equipment can be installed through the modules.

As depicted in FIG. 31, the completion equipment 350 includes a slottedliner. However, it will be appreciated that many other types andcombinations of completion equipment can be installed through themodules 202, 222, 224 in keeping with the principles of the invention.

During installation of the completion equipment 350, the valve module202 can be initially closed while the completion equipment is assembledand conveyed into the riser string 206 above the valve module. After thecompletion equipment 350 is in the upper riser string 206, and one ormore of the annular seal modules 222, 224, 226 seals off the annularspace 228 about the tubular string 212 above the completion equipment,the valve module 202 can be opened to allow the completion equipment andthe tubular string to be safely conveyed into the wellbore 346.

In this type of operation, the spacing between the annular sealmodule(s) and the valve module 202 should be long enough to accommodatethe length of the completion equipment 350. For example, a configurationsimilar to that shown in FIG. 26C could be used for this purpose.

Referring additionally now to FIG. 32, another configuration of theriser system 100 is representatively and schematically illustrated, inwhich the injection conduit 11 is connected to the drilling fluid returnline 342. Thus, instead of injecting the fluid composition 150 directlyinto the annular space 228 or flow passage 204 in the riser string 206,in the configuration of FIG. 32 the fluid composition is injected intothe drilling fluid return line 342.

In this manner, problems associated with, e.g., forming gas slugs in theriser string 206 may be avoided. The subsea choke 112, 117, 123 or 132can still be used to regulate back pressure on the annular space 228and, thus, the wellbore 346 (for example, during managed pressuredrilling), and the benefits of dual density and dual gradient drillingcan still be obtained, without flowing variable density fluids or gasthrough the subsea choke.

As depicted in FIG. 32, the fluid composition 150 is injected from theinjection conduit 11 into the drilling fluid return line 342 downstreamof the choke 117 and valves 115, 116 at outlet/inlet 44. However, thiscould be accomplished downstream of any of outlets/inlets 40, 45 or 54,as well.

In another feature of the configuration illustrated in FIG. 32, thefluid composition 150 may be injected into the drilling fluid returnline 342 at various different points along the return line. Valves 374are interconnected between the injection conduit 11 and the return line342 at spaced apart locations along the return line. Thus, a largedegree of flexibility is available in the riser system 100 forgas-lifting or otherwise utilizing dual density or dual gradientdrilling techniques with all, or any portion of, the return line 342between the outlet/inlet 44 and the surface rig structure 238.

The valves 374 may be controlled utilizing the subsea control system 142described above. The injection system illustrated in FIG. 32 may takethe place of the injection system 200 described above, or the two couldoperate in conjunction with each other. The injection system of FIG. 32could utilize valves similar to the valves 3 a, 3 b, chokes similar tochoke 14, non-return valves similar to the non-return valve 8, andsensors similar to the sensors 21 described above.

It may now be fully appreciated that the above description provides manyimprovements in the art of riser system construction, drilling methods,etc. The riser system 100 allows the tubular string 212 to be moved inand out of the well under pressure in a variety of different types ofdrilling operations, such as underbalanced (UBD), managed pressure (MPD)and normal drilling operations. The riser system 100 allows for variousinternal modules 202, 222, 224, 226 and anchoring device 210 to be runin on tubular string 212 and locked in place by hydraulic and/ormechanical means. The internal modules 202, 222, 224, 226 allow forannular isolation, well isolation, pipe rotation, diverting of flow,dynamic control of flow, and controlled fluid injection into the returnline 342 and/or into the riser string 206.

The riser system 100 enables utilization of a pressurized riser indeepwater drilling operations where an intermediate flex joint FJ isrequired, and where a riser fill up valve is required.

The riser system 100 allows isolation of the wellbore 346 from thesurface by closing the valve module 202. This permits introduction oflong completion tool strings (such as the completion equipment 350),bottom hole assemblies, etc., while still maintaining multiple flowpathsback to surface to continue managed pressure drilling operations.

The riser system 100 permits flexibility in dual gradient,underbalanced, managed pressure and normal drilling operations with theability to have chokes 112, 117, 123, 132 positioned subsea and in thereturn line 342, as well as the surface choke manifold CM. The subseaand surface choke systems can be linked and fully redundant. Thisremoves the complexity of the dual gradient fluid (e.g., the fluidcomposition 150) being in the return line 342 during well controloperations.

The riser system 100 allows dual gradient operations, without thedrilling fluid having to be pumped to surface from the sea bed, removingthe back pressure from the well, with the ability to have multipleinjection points along the return line 342 to surface, and theflexibility to position the internal modules 202, 222, 224, 226 anywherealong the riser string 206 from the slip joint SJ to the lower marineriser package LMRP.

The riser system 100 has the capability of having multiple annular sealmodules 222, 224, 226 installed in the riser string 206, in anycombination thereof. The seals 216, 218, 220 in the modules 222, 224,226 may be active or passive, control system or wellbore pressureoperated, and rotating or static. The module housings 268, 280, 282,284, 306 can accept modules provided by any manufacturer, which modulesare appropriately configured for the respective internal profiles, sealbores, etc.

The riser system 100 allows for full bore access through the riserstring 206 when the modules 202, 222, 224, 226 are removed, therefore,not imposing any restrictions on normal operations or procedures from afloating drilling vessel. In emergency situations, the modules 202, 222,224, 226 can be quickly retrieved and an operator can run conventionalhang-off tools through the riser string 206.

The riser system 100 allows all module housings 268, 280, 282, 284, 306to be deployed through the rotary table RT as normal riser sections.There preferably is no need for personnel to make connections or installequipment in the moon pool area of a rig 238 for the riser system 100.

The riser system 100 provides for continuous monitoring of flow rates,pressures, temperatures, valve positions, choke positions, valveintegrity (e.g., by monitoring pressure differential across valves)utilizing sensors 21, 111, 118, 124, 131, 340, 336, 338, 230. Thesensors are connected to subsea and surface control systems 119, 120,304, 142, 18, 19 for monitoring and control of all significant aspectsof the riser system 100.

The riser system 100 can accept deployment of an inner riser 36, ifneeded for increasing the pressure differential capability of the riserstring 206 below the annular seal modules 222, 224, 226.

The riser system 100 can utilize protective sleeves 35, 48 to protectports and seal bores 328, 330, 332, 334, 360 in the riser string 206when the respective modules are not installed. The inner diameters ofthe protective sleeves 35, 48 are preferably at least as great the innerdiameter of the conventional riser joints used in the riser string 206.

The riser system 100 permits the annular seal modules 222, 224 and/or226 to be installed in any order, and in any combination. The annularseal modules 222, 224 and/or 226 can all be positioned below the slipjoint SJ.

The latching profiles 358, 262, 266, 264 or latch actuators 278 andprofiles 270, 272, 274, 276, and seal bores 328, 330, 332, 334, 360 canbe standardized to allow interchangeability between different modulesand different types of modules.

The valve module 202 may be used in conjunction with a blind BOP at thewellhead structure 236 and/or a BOP module 42 in the riser system 100for redundant isolation between the wellbore 346 and the surface in theriser string 206.

In particular, the above description provides a riser system 100 whichmay include a valve module 202 which selectively permits and preventsfluid flow through a flow passage 204 extending longitudinally through ariser string 206.

An anchoring device 208 can releasably secure the valve module 202 inthe flow passage 204. The anchoring device 208 may be actuated from asubsea location exterior to the riser string 206.

Another anchoring device 210 may releasably secure a tubular string 212in the flow passage 204. The anchoring device 210 may preventdisplacement of the tubular string 212 relative to the riser string 206when pressure is increased in a portion of the riser string between thevalve module 202 and a seal 214, 216, 218 or 220 between the tubularstring 212 and the riser string 206.

An annular seal module 222, 224 or 226 may seal an annular space 228between the riser string 206 and the tubular string 212. The anchoringdevice 210 may prevent displacement of the tubular string 212 relativeto the riser string 206 when pressure is increased in a portion of theriser string between the valve module 202 and the annular seal module222, 224 or 226.

As discussed above, the riser system 100 may include one or more annularseal modules 222, 224, 226 which seal the annular space 228 between theriser string 206 and a tubular string 212 in the flow passage 204. Theannular seal module 222, 224 or 226 may include one or more seals 216,218, 220 which seal against the tubular string 212 while the tubularstring rotates within the flow passage 204. The seal 216, 218 may rotatewith the tubular string 212. The seal 220 may remain stationary withinthe riser string 206 while the tubular string 212 rotates within theseal 220. The seal 218 may be selectively radially extendable intosealing contact with the tubular string 212.

The riser system 100 may include at least one sensor 230 which senses atleast one parameter for monitoring operation of the valve module 202.

A method of pressure testing a riser string 206 has been described whichmay include the steps of: installing a valve module 202 into an internallongitudinal flow passage 204 extending through the riser string 206;closing the valve module 202 to thereby prevent fluid flow through theflow passage 204; and applying a pressure differential across the closedvalve module 202, thereby pressure testing at least a portion of theriser string 206.

The installing step may include securing the valve module 202 in aportion of the flow passage 204 disposed between opposite endconnections 232, 234 of the riser string 206. The lower end connection234 may secure the riser string 206 to a subsea wellhead structure 236,and the upper end connection 232 may secure the riser string 206 to arig structure 238. The upper end connection 232 may rigidly secure theriser string 206 to the rig structure 238.

The method may further include the step of installing an annular sealmodule 222, 224 or 226 into the flow passage 204, with the annular sealmodule being operative to seal an annular space 228 between the riserstring 206 and a tubular string 212 positioned within the flow passage204. The pressure differential applying step may include increasingpressure in the flow passage 204 between the valve module 202 and theannular seal module 222, 224 or 226.

The method may further include the step of installing another annularseal module 222, 224 or 226 into the flow passage 204, with the secondannular seal module being operative to seal the annular space 228between the riser string 206 and the tubular string 212 positionedwithin the flow passage 204. The pressure differential applying step mayfurther include increasing pressure in the flow passage 204 between thevalve module 202 and the second annular seal module 222, 224 or 226.

The method may further include the step of increasing pressure in theriser string 206 between the first and second annular seal modules 222,224 and/or 226, thereby pressure testing the riser string between thefirst and second annular seal modules.

In the pressure differential applying step, the portion of the riserstring 206 which is pressure tested may be between the valve module 202and an end connection 234 of the riser string 206 which is secured to awellhead structure 236.

The method may also include the steps of: conveying a tubular string 212into the flow passage 204; and sealing and securing the tubular stringat a position in the flow passage, so that fluid flow is preventedthrough an annular space 228 between the riser string 206 and thetubular string 212, and the pressure differential applying step mayfurther include applying increased pressure via the tubular string 212to the portion of the riser string 206 which is disposed between thevalve module 202 and the position at which the tubular string 212 issealed and secured in the flow passage 204.

The method may further include the step of utilizing at least one sensor111, 118, 124 and/or 131 to monitor pressure within the riser portionduring the pressure differential applying step.

Also described above is a method of constructing a riser system 100. Themethod may include the steps of: installing a valve module 202 in a flowpassage 204 extending longitudinally through a riser string 206, thevalve module 202 being operative to selectively permit and prevent fluidflow through the flow passage 204; and installing at least one annularseal module 222, 224 and/or 226 in the flow passage 204, the annularseal module being operative to prevent fluid flow through an annularspace 228 between the riser string 206 and a tubular string 212positioned in the flow passage 204.

The method may include the steps of providing an internal location 240for sealing and securing the valve module 202 in the flow passage 204,and providing another location 242, 244 and/or 246 for sealing andsecuring the annular seal module 222, 224, 226 in the flow passage, andwherein a minimum internal dimension ID of the riser string 206 at eachof these locations 240, 242, 244, 246 is at least as great as a minimuminternal dimension of the riser string between opposite end connections232, 234 of the riser string.

The valve module 202 and annular seal module 222, 224, 226 installingsteps may also each include actuating an anchoring device 208, 248, 250,252 to secure the respective module relative to the riser string 206.The actuating step may include engaging a latch member 254, 256, 258,260 of the respective module 202, 222, 224, 226 with a correspondinginternal profile 262, 264, 266 formed in the riser string 206. Theactuating step may include displacing a respective latch member 254,256, 258, 260 into engagement with a corresponding external profile 270,272, 274, 276 formed on the respective module 202, 222, 224, 226, andwherein a respective actuator 278 on an exterior of the riser string 206causes displacement of the respective latch member 254, 256, 258, 260.

The method may include the steps of: interconnecting a valve modulehousing 280 as part of the riser string 206; and interconnecting anannular seal module housing 282, 284 and/or 306 as part of the riserstring. Each of the interconnecting steps may include displacing therespective module housing 280, 282, 284, 306 through a rotary table RT.The displacing step may include displacing the respective module housing280, 282, 284, 306 through the rotary table RT with at least one of avalve 113, 114, 115, 116, 121, 122, 133 and/or 134 and an accumulator 56externally connected to the respective module housing 280, 282, 284,306.

The riser string 206 may include a portion 308 or section 30 having atleast one valve 310, 113, 114, 115, 116, 121, 122, 133 and/or 134, atleast one accumulator 312 and/or 56, and at least one actuator 314and/or 278 externally connected to the riser portion for operation ofthe valve and annular seal modules 202, 222, 224 and/or 226. The methodmay also include the step of displacing the riser portion 308 or section30 with the externally connected valve 310, 113, 114, 115, 116, 121,122, 133 and/or 134, accumulator 312 and/or 56 and actuator 314 and/or278 through a rotary table RT.

The method may include the steps of connecting hydraulic control lines90, 316, 318 externally to the riser string 206 for operation of thevalve and annular seal modules 202, 222, 224 and/or 226, and connectingthe hydraulic control lines to a subsea hydraulic control system 304external to the riser string 206. The method may also include the stepof replacing the hydraulic control system 304 using a subsea remotelyoperated vehicle 320.

The method may include the step of connecting a hydraulic supply line 90and an electrical control line 89 between the subsea hydraulic controlsystem 304 and a surface hydraulic control system 18. Signals foroperating the subsea hydraulic control system 304 to selectively supplyhydraulic fluid to operate the valve and annular seal modules 202, 222,224 and/or 226 may be multiplexed on the electrical control line 89.

The method may include the step of connecting at least one lubricationsupply line 53 or 322 externally to the riser string 206 for lubricatinga bearing assembly 324 of the annular seal module 222, 224. The methodmay include the step of connecting at least one lubrication return line326 externally to the riser string 206 for returning lubricant from thebearing assembly 324.

The annular seal module 222, 224, 226 includes at least one seal 216,218, 220 which seals against the tubular string 212 while the tubularstring rotates within the flow passage 204. The seal 216 or 218 mayrotate with the tubular string 212. The seal 220 may remain stationarywithin the riser string 206 while the tubular string 212 rotates withinthe seal 220. The seal 218 may be selectively radially extendable intosealing contact with the tubular string 212.

The valve and annular seal module 202, 222, 224, 226 installing stepsmay include sealing the respective module in a corresponding seal bore328, 330, 332, 334 formed in the riser string 206. The method mayfurther include the steps of retrieving a respective seal bore protectorsleeve 35, 48 from within the corresponding seal bore 328, 330, 332, 334prior to the steps of installing the respective one of the valve andannular seal modules 202, 222, 224, 226.

The method may include the step of retrieving a seal bore protectorsleeve 35, 48 from within the riser string 206 prior to the step ofinstalling the valve module 202. The method may include the step ofretrieving a seal bore protector sleeve 35, 48 from within the riserstring 206 prior to the step of installing the annular seal module 222,224, 226.

The method may include utilizing at least one sensor 111, 118, 124, 131to monitor pressure in the flow passage 204 between the valve module 202and the annular seal module 222, 224 or 226. The method may includeutilizing at least one sensor 230, 336, 338, 340 to monitor at least oneparameter indicative of a performance characteristic of at least one ofthe valve and annular seal modules 202, 222, 224, 226.

A drilling method is also described which may include the steps of:connecting an injection conduit 11 externally to a riser string 206, sothat the injection conduit is communicable with an internal flow passage204 extending longitudinally through the riser string 206; installing anannular seal module 222, 224, 226 in the flow passage 204, the annularseal module being positioned in the flow passage between opposite endconnections 232, 234 of the riser string 206; conveying a tubular string212 into the flow passage 204; sealing an annular space 228 between thetubular string 212 and the riser string 206 utilizing the annular sealmodule 222, 224, 226; rotating the tubular string 212 to thereby rotatea drill bit 348 at a distal end of the tubular string, the annular sealmodule 222, 224, 226 sealing the annular space 228 during the rotatingstep; flowing drilling fluid 81 from the annular space 228 to a surfacelocation; and injecting a fluid composition 150 having a density lessthan that of the drilling fluid into the annular space 228 via theinjection conduit 11.

In the injecting step, the fluid composition 150 may include Nitrogengas. The fluid composition 150 may include hollow glass spheres. Thefluid composition 150 may include a mixture of liquid and gas.

The riser string 206 may include a portion 1 having at least one valve8, 3 a, 3 b, 6 a, 6 b at least one accumulator 5, 15, and at least oneactuator 4 a, 4 b externally connected to the riser portion 1 forcontrolling injection of the fluid composition 150. The method mayinclude displacing the riser portion 1 with the externally connectedvalve 8, 3 a, 3 b, 6 a, 6 b accumulator 5, 15 and actuator 4 a, 4 b,through a rotary table RT.

The method may include the steps of connecting hydraulic control lines7, 9, 17 externally to the riser string 84, 206 for controllinginjection of the fluid composition 150, and connecting the hydrauliccontrol lines to a subsea hydraulic control system 142 external to theriser string 84, 206. The method may include replacing the hydrauliccontrol system 142 utilizing a subsea remotely operated vehicle 320. Themethod may include connecting a hydraulic supply line 9 and anelectrical control line 20 between the subsea hydraulic control system142 and a surface hydraulic control system 18. Signals for operating thesubsea hydraulic control system 142 to selectively supply hydraulicfluid to control injection of the fluid composition 150 may bemultiplexed on the electrical control line 20.

The method may include utilizing at least one sensor 21 to monitorpressure in the injection conduit 11.

A drilling method is also described which may include the steps of:connecting a drilling fluid return line 88, 194, 342 externally to ariser string 84, 206, so that the drilling fluid return line iscommunicable with an internal flow passage 204 extending longitudinallythrough the riser string; installing an annular seal module 222, 224,226 in the flow passage 204, the annular seal module being positioned inthe flow passage between opposite end connections 232, 234 of the riserstring; conveying a tubular string 212 into the flow passage 204;sealing an annular space 228 between the tubular string 212 and theriser string 206 utilizing the annular seal module 222, 224, 226;rotating the tubular string 212 to thereby rotate a drill bit 348 at adistal end of the tubular string, the annular seal module 222, 224, 226sealing the annular space 228 during the rotating step; and flowingdrilling fluid 81 from the annular space 228 to a surface location viathe drilling fluid return line 342, the flowing step including varying aflow restriction through a subsea choke 112, 117, 123, 132 externallyconnected to the riser string 206 to thereby maintain a desired downholepressure.

The step of varying the flow restriction may include automaticallyvarying the flow restriction without human intervention to therebymaintain the desired downhole pressure.

The riser string 206 may include a portion 308 having at least one valve310, at least one accumulator 312, and at least one actuator 314externally connected to the riser portion for operating the subsea choke112, 117, 123, 132. The method may further include displacing the riserportion 308 with the externally connected valve 310, accumulator 312 andactuator 314 through a rotary table RT.

The method may include connecting hydraulic control lines 87, 93externally to the riser string 84, 206 for controlling operation of thechoke 112, 117, 123, 132, and connecting the hydraulic control lines toa subsea hydraulic control system 119, 120 external to the riser string84, 206. The method may include connecting the hydraulic control line87, 93 and at least one electrical control line 186, 192 between thesubsea hydraulic control system 119, 120 and a surface hydraulic controlsystem 18. Signals for operating the subsea hydraulic control system119, 120 to selectively supply hydraulic fluid to control operation ofthe choke 112, 117, 123, 132 may be multiplexed on the electricalcontrol line 186, 192.

The method may include utilizing at least one sensor 111, 118, 124, 131to monitor pressure in the drilling fluid return line 88, 194.

Another drilling method is described which may include the steps of:installing a first annular seal module 222, 224 or 226 in an internalflow passage 204 extending longitudinally through a riser string 206,the first annular seal module being secured in the flow passage betweenopposite end connections 232, 234 of the riser string; sealing anannular space 228 between the riser string 206 and a tubular string 212in the flow passage 204 utilizing the first annular seal module 222, 224or 226, the sealing step being performed while the tubular stringrotates within the flow passage; and then conveying a second annularseal module 222, 224 or 226 into the flow passage 204 on the tubularstring 212.

The tubular string 212 may remain in the flow passage 204 between theopposite end connections 232, 234 of the riser string 206 continuouslybetween the sealing and conveying steps.

The method may include sealing the annular space 228 between the riserstring 206 and the tubular string 212 in the flow passage 204 utilizingthe second annular seal module 222, 224 or 226, while the tubular stringrotates within the flow passage.

The second annular seal module 222, 224 or 226 may include at least oneseal 216, 218, 220 which seals against the tubular string 212 while thetubular string rotates within the flow passage 204. The seal 216, 218may rotate with the tubular string 212. The seal 220 may remainstationary within the riser string 206 while the tubular string 212rotates within the seal. The seal 218 may be selectively radiallyextendable into sealing contact with the tubular string 212.

The method may include utilizing at least one sensor 118, 124, 131 tomonitor pressure in the flow passage 204 between the first and secondannular seal modules 222, 224, 226.

A further method is described which may include the steps of: installingmultiple modules 202, 222, 224 and/or 226 in an internal flow passage204 extending longitudinally through a riser string 206, the modulesbeing installed in the flow passage between opposite end connections232, 234 of the riser string; inserting a tubular string 212 through aninterior of each of the modules 202, 222, 224 and/or 226; and thensimultaneously retrieving the multiple modules 202, 222, 224 and/or 226from the flow passage 204 on the tubular string 212.

The retrieving step may include operating anchoring devices 208, 248,250, 252 for the respective modules to thereby release the modules 202,222, 224, 226 for displacement relative to the riser string 206. Each ofthe anchoring devices 208, 248, 250, 252 may include an actuator 278externally connected to the riser string 206. At least one of theanchoring devices 278 may be operable by a subsea remotely operatedvehicle 320 from an exterior of the riser string 206.

The modules 202, 222, 224, 226 may include at least one annular sealmodule 222, 224, 226 which seals an annular space 228 between thetubular string 212 and the riser string 206. The modules 202, 222, 224,226 may include at least one valve module 202 which selectively permitsand prevents fluid flow through the flow passage 204.

A drilling method is described above which includes the steps of:sealing an annular space 228 between a tubular string 212 and a riserstring 206; flowing drilling fluid from the annular space to a surfacelocation via a drilling fluid return line 342; and injecting a fluidcomposition 150 having a density less than that of the drilling fluidinto the drilling fluid return line via an injection conduit 11.

The fluid composition 150 may include Nitrogen gas, hollow glass spheresand/or a mixture of liquid and gas.

The injecting step may include selecting from among multiple connectionpoints between the drilling fluid return line 342 and the injectionconduit 11 for injecting the fluid composition 150 into the drillingfluid return line.

The method may include the steps of connecting hydraulic control lines7, 9, 17 externally to the riser string 206 for controlling injection ofthe fluid composition 150, and connecting the hydraulic control lines toa subsea hydraulic control system 142 external to the riser string 206.

The injecting step may include injecting the fluid composition 150 intothe drilling fluid return line 342 downstream from a subsea choke 112,117, 123 or 132 which variably regulates flow through the drilling fluidreturn line. The injecting step may include injecting the fluidcomposition 150 into the drilling fluid return line 342 at a positionbetween a surface location and a subsea choke 112, 117, 123 or 132interconnected in the drilling fluid return line.

A drilling method described above includes the steps of: installing anannular seal module 222, 224 or 226 in an internal flow passage 204extending longitudinally through a riser string 206, the annular sealmodule being secured in the flow passage between opposite endconnections 232, 234 of the riser string; then conveying a secondannular seal module 222, 224 or 226 into the flow passage 204; andsealing an annular space 228 between the riser string and a tubularstring 212 in the flow passage utilizing the first and second annularseal modules.

The sealing step may include sealing the annular space 228 between theriser string 206 and the tubular string 212 in the flow passage 204utilizing the first and second annular seal modules 222, 224, 226 whilethe tubular string rotates within the flow passage.

Each of the annular seal modules may include at least one seal 216, 218,220 which seals against the tubular string 212 while the tubular stringrotates within the flow passage 204. The seal 216, 218 may rotate withthe tubular string 212. The seal 220 may remain stationary within theriser string 206 while the tubular string 212 rotates within the seal.The seal 218 may be selectively radially extendable into sealing contactwith the tubular string 212.

The method may include the step of utilizing at least one sensor 118,124, 131 to monitor pressure in the flow passage between the first andsecond annular seal modules 222, 224, 226.

Another drilling method described above includes the steps of:installing an annular seal module 222, 224, 226 in an internal flowpassage 204 extending longitudinally through a riser string 206, theannular seal module being secured in the flow passage between oppositeend connections 232, 234 of the riser string; then conveying on atubular string 212 at least one seal 216, 218, 220 into the annular sealmodule 222, 224, 226; and sealing an annular space 228 between the riserstring 206 and the tubular string 212 in the flow passage 204 utilizingthe seal 216, 218, 220, the sealing step being performed while a drillbit 348 on the tubular string 212 is rotated.

The method may also include the steps of installing another annular sealmodule 222, 224, 226 in the flow passage 204, and then conveying on thetubular string 212 at least one other seal 216, 218, 220 into the secondannular seal module.

The method may also include the step of sealing the annular space 228between the riser string 206 and the tubular string 212 in the flowpassage 204 utilizing the first annular seal module 222, 224, 226, whilethe drill bit 348 rotates.

The first seal 216, 218, 220 may seal against the tubular string 212while the drill bit 348 rotates. The first seal 216, 218, 220 may rotatewith the tubular string 212 while the tubular string rotates with thedrill bit 348. The first seal 216, 218, 220 may remain stationary withinthe riser string 206 while the tubular string 212 rotates within thefirst seal. The first seal 216, 218, 220 may be selectively radiallyextendable into sealing contact with the tubular string 212.

The method may include the step of retrieving on the tubular string 212the first seal 216, 218, 220 from the riser string 206.

The tubular string 212 may or may not rotate during drilling operations.For example, if a mud motor (which rotates a drill bit on an end of atubular string in response to circulation of mud or other drilling fluidthrough the motor) is used, drilling operations can be performed withoutrotating the tubular string 212. The annular seal modules 222, 224, 226can seal off the annular space 228 whether or not the tubular string 212rotates during drilling, completion, stimulation, etc. operations.

While specific embodiments have been shown and described, modificationscan be made by one skilled in the art without departing from the spiritor teaching of this invention. The embodiments as described areexemplary only and are not limiting. Many variations and modificationsare possible and are within the scope of the invention. Accordingly, thescope of protection is not limited to the embodiments described, but isonly limited by the claims that follow, the scope of which shall includeall equivalents of the subject matter of the claims.

Of course, a person skilled in the art would, upon a carefulconsideration of the above description of representative embodiments ofthe invention, readily appreciate that many modifications, additions,substitutions, deletions, and other changes may be made to the specificembodiments, and such changes are contemplated by the principles of thepresent invention. Accordingly, the foregoing detailed description is tobe clearly understood as being given by way of illustration and exampleonly, the spirit and scope of the present invention being limited solelyby the appended claims and their equivalents.

What is claimed is:
 1. A method of constructing a riser system, themethod comprising the steps of: installing a valve module in a flowpassage extending longitudinally through a riser string, the valvemodule configured to selectively permit and prevent fluid flow throughthe flow passage; installing at least one annular seal module in theflow passage, the annular seal module configured to prevent fluid flowthrough an annular space between the riser string and a tubular stringpositioned in the flow passage; and retrieving the valve module andannular seal module simultaneously from the riser system.
 2. The methodof claim 1, further comprising the steps of providing a first internallocation for sealing and securing the valve module in the flow passage,and providing at least a second location for sealing and securing theannular seal module in the flow passage, and wherein a minimum internaldimension of the riser string at each of the first and second locationsis at least as great as a minimum internal dimension of the riser stringbetween opposite end connections of the riser string.
 3. The method ofclaim 1, wherein each of the valve module and annular seal moduleinstalling steps further comprises actuating an anchoring device tosecure the respective module relative to the riser string.
 4. The methodof claim 3, wherein the actuating step further comprises selectivelyengaging a latch member of the respective module with a correspondinginternal profile formed in the riser string.
 5. The method of claim 3,wherein the actuating step further comprises displacing a respectivelatch member into engagement with a corresponding external profileformed on the respective module, and wherein a respective actuator on anexterior of the riser string causes displacement of the respective latchmember.
 6. The method of claim 1, further comprising the steps of:interconnecting a valve module housing as part of the riser string; andinterconnecting an annular seal module housing as part of the riserstring, and wherein each of the interconnecting steps further comprisesdisplacing the respective module housing through a rotary table.
 7. Themethod of claim 6, wherein the displacing step further comprisesdisplacing the respective module housing through the rotary table withat least one of a valve and an accumulator externally connected to therespective module housing.
 8. The method of claim 1, wherein the riserstring includes a portion having at least one valve, at least oneaccumulator, and at least one actuator externally connected to the riserportion for operation of the valve and annular seal modules, and whereinthe method further comprises the step of displacing the riser portionwith the externally connected valve, accumulator and actuator through arotary table.
 9. The method of claim 1, further comprising the steps ofconnecting hydraulic control lines externally to the riser string foroperation of the valve and annular seal modules, and connecting thehydraulic control lines to a subsea hydraulic control system external tothe riser string.
 10. The method of claim 9, further comprising the stepof replacing the hydraulic control system using a subsea remotelyoperated vehicle.
 11. The method of claim 9, further comprising the stepof connecting a hydraulic supply line and an electrical control linebetween the subsea hydraulic control system and a surface hydrauliccontrol system.
 12. The method of claim 11, wherein signals foroperating the subsea hydraulic control system to selectively supplyhydraulic fluid to operate the valve and annular seal modules aremultiplexed on the electrical control line.
 13. The method of claim 1,further comprising the step of connecting at least one lubricationsupply line externally to the riser string for lubricating a bearingassembly of the annular seal module.
 14. The method of claim 13, furthercomprising the step of connecting at least one lubrication return lineexternally to the riser string for returning lubricant from the bearingassembly.
 15. The method of claim 1, wherein the annular seal moduleincludes at least one seal which seals against the tubular string whilethe tubular string rotates within the flow passage.
 16. The method ofclaim 15, wherein the seal rotates with the tubular string.
 17. Themethod of claim 15, wherein the seal remains stationary within the riserstring while the tubular string rotates within the seal.
 18. The methodof claim 15, wherein the seal is selectively radially extendable intosealing contact with the tubular string.
 19. The method of claim 1,wherein each of the valve and annular seal module installing stepsfurther comprises sealing the respective module in a corresponding sealbore formed in the riser string, and the method further comprising thesteps of retrieving a respective seal bore protector sleeve from withinthe corresponding seal bore prior to the steps of installing therespective one of the valve and annular seal modules.
 20. The method ofclaim 1, further comprising the step of retrieving a seal bore protectorsleeve from within the riser string prior to the step of installing thevalve module.
 21. The method of claim 1, further comprising the step ofretrieving a seal bore protector sleeve from within the riser stringprior to the step of installing the annular seal module.
 22. The methodof claim 1, further comprising the step of utilizing at least one sensorto monitor pressure in the flow passage between the valve module and theannular seal module.
 23. The method of claim 1, further comprising thestep of utilizing at least one sensor to monitor at least one parameterindicative of a performance characteristic of at least one of the valveand annular seal modules.